Genetically encoded biosensors

ABSTRACT

The present disclosure provides, inter alia, genetically encoded recombinant peptide biosensors comprising analyte-binding framework portions and signaling portions, wherein the signaling portions are present within the framework portions at sites or amino acid positions that undergo a conformational change upon interaction of the framework portion with an analyte.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Application No. 61/544,867 filed Oct. 7, 2011.

TECHNICAL FIELD

This disclosure relates to genetically encoded biosensors and methods for the design, production, and use of such biosensors.

BACKGROUND

Protein-based sensors that transduce microscopic binding events into macroscopically observable signals are available to allow real-time visualization of a variety of biological events and/or molecules (Frommer et al., Chem. Soc. Rev., 38:2833-2841, 2009). Such sensors can be targeted and/or expressed in living cells, tissues, and organisms, and permit imaging with minimally invasive techniques (Okumoto, Curr. Opin. Biotechnol., 21:45-54, 2010). Application of these sensors is limited by the narrow range of analytes that can be detected and/or by their inability to distinguish signal over noise.

SUMMARY

The present disclosure provides genetically encoded recombinant peptides containing an analyte-binding framework portion linked (e.g., operably linked) to a signaling portion, wherein the signaling portion is allosterically regulated by the framework portion upon interaction of the framework portion with an analyte (e.g., a defined, selected, and/or specific analyte). These constructs can be used as biosensors, e.g., to transduce microscopic binding events into macroscopically observable signals.

The present disclosure provides, in part, recombinant peptides for use as biosensors (e.g., recombinant peptide biosensors) that include (e.g., comprise, consist essentially of, or consist of), e.g., include at least, an analyte-binding framework portion and a signaling portion. As described in further detail herein, such signaling portions are present within the framework portion at a site or amino acid position that undergoes a conformational change (e.g., a conformational change sufficient to alter a physical and/or functional characteristic of the signaling portion, e.g., a substantial conformational change) upon interaction of the framework portion with a defined, specific, or selected analyte (e.g. such as an analyte to which the framework portion or a region thereof, and/or the biosensor, specifically binds). For example, in some instances, the signaling portion is allosterically regulated by the framework portion such that signaling from the signaling portion is altered (e.g. wherein a first level of signaling is altered or changed to a second level of signaling that can be distinguished using routine methods of detection from the first) upon interaction of the framework portion with the analyte. In some instances, signaling by the signaling portion can detectably increase or decrease upon interaction of the framework portion with the analyte. In some instances, signaling by the signaling portion upon interaction of the biosensor with a defined, specific, or selected analyte (e.g. such as an analyte to which the framework portion or a region thereof, and/or the biosensor, specifically binds) can be proportional or can correlate with to the level of interaction between the framework portion and the analyte such that the level of interaction can be determined from the signaling or alteration thereof.

In some instances, framework portions of the biosensors disclosed herein have a first structure in the absence of an analyte and a second structure that is detectably distinct from the first structure in the presence of the analyte. In some instances, the conformational change between the first structure and the second structure allosterically regulates the signaling portion.

In some instances, framework portions of the biosensors disclosed herein can be, or can include (e.g., comprise, consist essentially of, or consist of), periplasmic binding proteins (PBP) or variants of a PBP. In some instances, exemplary PBPs or variants thereof can include, but are not limited to, peptides with at least 90% identity to a peptide selected from the group consisting of SEQ ID NO:105, SEQ ID NO: 106, SEQ ID NO:107, SEQ ID NO:108, SEQ ID NO:109, SEQ ID NO: 110, SEQ ID NO:111, SEQ ID NO:113, and SEQ ID NO:114. In some instances, exemplary PBPs or variants thereof can include, but are not limited to, peptides with at least 95% identity to a peptide selected from the group consisting of SEQ ID NO:105, SEQ ID NO: 106, SEQ ID NO:107, SEQ ID NO:108, SEQ ID NO:109, SEQ ID NO: 110, SEQ ID NO:111, SEQ ID NO:113, and SEQ ID NO:114. In some instances, exemplary PBPs or variants thereof can include, but are not limited to, peptides selected from the group consisting of SEQ ID NO:105, SEQ ID NO: 106, SEQ ID NO:107, SEQ ID NO:108, SEQ ID NO:109, SEQ ID NO: 110, SEQ ID NO:111, SEQ ID NO:113, and SEQ ID NO:114. In some instances, exemplary PBPs or variants thereof can include, but are not limited to, peptides selected from the group consisting of SEQ ID NO:105, SEQ ID NO: 106, SEQ ID NO:107, SEQ ID NO:108, SEQ ID NO:109, SEQ ID NO: 110, SEQ ID NO:111, SEQ ID NO:113, and SEQ ID NO:114 comprising 10 or fewer conservative amino acid substitutions. PBPs or variants thereof disclosed herein can be truncated.

In some instances, signaling portions of the biosensors disclosed herein can be or can include (e.g., comprise, consist essentially of, or consist of) one or more (e.g., one, two three, four, five, and less than ten) circularly permuted fluorescent proteins (cpFPs). Such cpFPs can be include but are not limited to, for example, green fluorescent proteins, yellow fluorescent proteins, red fluorescent proteins, and/or blue fluorescent proteins.

In some instances, biosensors disclosed herein, e.g., analyte-binding framework portions of biosensors disclosed herein, can bind (e.g., bind specifically) to glucose. Such sensors can be referred to as glucose binding biosensors or glucose biosensors.

In some instances, biosensors disclosed herein, e.g., analyte-binding framework portions of biosensors disclosed herein, can bind (e.g., bind specifically) to maltose. Such sensors can be referred to as maltose binding biosensors or maltose biosensors.

In some instances, biosensors disclosed herein, e.g., analyte-binding framework portions of biosensors disclosed herein, can bind (e.g., bind specifically) to phosphonate. Such sensors can be referred to as phosphonate binding biosensors or phosphonate biosensors.

In some instances, biosensors disclosed herein, e.g., analyte-binding framework portions of biosensors disclosed herein, can bind (e.g., bind specifically) to glutamate. Such sensors can be referred to as glutamate binding biosensors or glutamte biosensors.

In some instances, biosensors disclosed herein can include (e.g., comprise, consist essentially of, or consist of): an amino acid sequence with at least 90% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, and 53, wherein the recombinant peptide biosensor binds specifically to maltose; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, and 53 comprising 10 or fewer conservative amino acid substitutions, wherein the recombinant peptide biosensor binds specifically to maltose; and/or a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, and 53.

In some instances, biosensors disclosed herein can include (e.g., comprise, consist essentially of, or consist of): an amino acid sequence with at least 90% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 62 and 63, wherein the recombinant peptide biosensor binds specifically to glutamate; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 62 and 63 comprising 10 or fewer conservative amino acid substitutions, wherein the recombinant peptide biosensor binds specifically to glutamate; and/or a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 62 and 63.

In some instances, biosensors disclosed herein can include (e.g., comprise, consist essentially of, or consist of): an amino acid sequence with at least 90% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 77 and 78, wherein the recombinant peptide biosensor binds specifically to phosphonate; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 77 and 78 comprising 10 or fewer conservative amino acid substitutions, wherein the recombinant peptide biosensor binds specifically to phosphonate; and/or a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 77 and 78.

In some instances, biosensors disclosed herein can include (e.g., comprise, consist essentially of, or consist of): an amino acid sequence with at least 90% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 91, 92, 93 and 94, wherein the recombinant peptide biosensor binds specifically to glucose; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 91, 92, 93 and 94 comprising 10 or fewer conservative amino acid substitutions, wherein the recombinant peptide biosensor binds specifically to glucose; and/or a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 91, 92, 93 and 94.

In some instances, biosensors disclosed herein can include (e.g., comprise, consist essentially of, or consist of): SEQ ID NO:91; SEQ ID NO:92; SEQ ID NO:93; SEQ ID NO:95.

In some instances, any recombinant biosensor disclosed herein can be isolated and/or purified. The terms “isolated” or “purified,” when applied to a biosensor disclosed herein includes nucleic acid proteins and peptides that are substantially free or free of other cellular material or culture medium when produced by recombinant techniques, or substantially free or free of precursors or other chemicals when chemically synthesized.

The disclosure also provides, in part, nucleic acids (e.g., isolated and/or purified nucleic acids) encoding any one or more of the recombinant peptide biosensors disclosed herein. For example, nucleic acids can encode: an amino acid sequence with at least 90% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, and 53, wherein the recombinant peptide biosensor binds specifically to maltose; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, and 53 comprising 10 or fewer conservative amino acid substitutions, wherein the recombinant peptide biosensor binds specifically to maltose; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, and 53; an amino acid sequence with at least 90% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 62 and 63, wherein the recombinant peptide biosensor binds specifically to glutamate; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 62 and 63 comprising 10 or fewer conservative amino acid substitutions, wherein the recombinant peptide biosensor binds specifically to glutamate; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 62 and 63; an amino acid sequence with at least 90% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 77 and 78, wherein the recombinant peptide biosensor binds specifically to phosphonate; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 77 and 78 comprising 10 or fewer conservative amino acid substitutions, wherein the recombinant peptide biosensor binds specifically to phosphonate; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 77 and 78; an amino acid sequence with at least 90% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 91, 92, 93 and 94, wherein the recombinant peptide biosensor binds specifically to glucose; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 91, 92, 93 and 94 comprising 10 or fewer conservative amino acid substitutions, wherein the recombinant peptide biosensor binds specifically to glucose; a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 91, 92, 93 and 94; and/or SEQ ID NO:91; SEQ ID NO:92; SEQ ID NO:93; SEQ ID NO:95.

In some instances, the disclosure includes vectors containing one or a plurality of the nucleic acids disclosed herein and cells containing such vectors. In some instances, the disclosure provides cells containing one or a plurality of nucleic acids disclosed herein.

In some instances, the disclosure includes kits related to the biosensors and nucleic acids disclosed herein Such kits can include or contain, for example, a biosensor, a nucleic acid encoding a biosensor, vectors, and/or cells, provided herein.

In some instances, the disclosure provides methods related to the biosensors and nucleic acids disclosed herein. Such methods can include methods of making, using, and/or selling the biosensors and nucleic acids disclosed herein. For example, methods can include methods for producing genetically encoded recombinant peptide biosensors. In such instances, methods can include, for example, selecting a framework portion that binds specifically to a target analyte and that undergoes a conformational change upon interacting binding to the target analyte, identifying a site or amino acid position within the selected framework portion where or around which the conformational change occurs, and inserting a signaling portion into the site or amino acid position. In some instances, framework portions include periplasmic binding proteins (PBPs) disclosed herein. Exemplary PBPs include PBPs that bind (e.g., bind specifically) to glucose.

In some instances, the present disclosure includes methods for detecting glucose, e.g., in a sample containing a level of glucose. Such methods can include, detecting a level of fluorescence emitted by a recombinant peptide biosensor, the peptide biosensor having an amino acid sequence selected from the group consisting of SEQ ID NO: 91, 92, 93 and 94, and correlating the level of fluorescence with the presence of glucose. In some instances, recombinant peptide biosensors used in the methods herein are expressed from nucleic acids. In some instances, methods include contacting the recombinant peptide biosensor with a test sample (e.g., a sample comprising glucose). In some instances, methods can include the level of fluorescence emitted by a biosensor (e.g., a biosensor bound to glucose) with a concentration glucose in the sample. Such correlation can include, for example, comparing the level of fluorescence with a level of fluorescence emitted by the recombinant peptide biosensor in the presence of a sample comprising a known concentration or range of concentrations of glucose. In some instance, the level of fluorescence emitted by the recombinant peptide biosensor in the presence (e.g., bound or bound specifically to) of a sample comprising a known concentration or range of concentrations of glucose is stored on an electronic database.

One of skill will appreciate that such methods can be adapted for any defined, specific, or selected analyte. For example, in some instances, the disclosure provides methods for detecting a defined, selected, or specific analyte. These methods can include detecting a level of fluorescence emitted by a recombinant peptide biosensor expressed from a nucleic acid and correlating the level of fluorescence with the presence the defined, selected, or specific analyte. In some instances, methods include contacting the recombinant peptide biosensor with a sample comprising the analyte. In some instances, methods include correlating the level of fluorescence with a concentration of the analyte. In some instances, methods include comparing the level of fluorescence with a level of fluorescence emitted by the recombinant peptide biosensor in the presence of a sample comprising a known concentration or range of concentrations of the analyte, wherein the level of fluorescence emitted by the recombinant peptide biosensor in the presence of a sample comprising a known concentration or range of concentrations of the analyte is stored on an electronic database.

In some instances, the present disclosure provides methods for detecting a defined, selected, or specific analyte, the method comprising detecting a level of fluorescence emitted by a recombinant peptide biosensor of any one of claims 1-36; and correlating the level of fluorescence with the presence of a defined, selected, or specific analyte. In some instances, recombinant peptide biosensors can be expressed from a nucleic acid. In some instances, methods can include contacting the recombinant peptide biosensor with a sample comprising the analyte. In some instances, methods can include correlating the level of fluorescence with a concentration of the analyte and, optionally, comparing the level of fluorescence with a level of fluorescence emitted by the recombinant peptide biosensor in the presence of a sample comprising a known concentration or range of concentrations of the analyte. In some instances, the level of fluorescence emitted by the recombinant peptide biosensor in the presence of a sample comprising a known concentration or range of concentrations of the analyte is stored on an electronic database.

Methods herein can be performed in vitro.

In some instances, the present disclosure provides compositions containing any one or a plurality of the peptide biosensors and/or nucleic acids disclosed herein.

Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Methods and materials are described herein for use in the present invention; other, suitable methods and materials known in the art can also be used. The materials, methods, and examples are illustrative only and not intended to be limiting. All publications, patent applications, patents, sequences, database entries, and other references mentioned herein are incorporated by reference in their entirety. In case of conflict, the present specification, including definitions, will control.

Other features and advantages of the invention will be apparent from the following detailed description and figures, and from the claims.

DESCRIPTION OF DRAWINGS

FIG. 1|Cartoon representation showing ligand bound Escherichia Coli malto-dextrin-binding protein (EcMBP) and potential circularly-permuted fluorescent protein (cpFP) insertion sites.

FIG. 2|Cartoon representation showing ligand bound Pyrococcus furiosus maltotriose binding protein (PfMBP) and potential cpFP insertion sites.

FIG. 3|Cartoon representation showing ligand bound E. coli glutamate-binding protein (EcYbeJ) and potential cpFP insertion sites.

FIG. 4|Cartoon representation showing ligand bound E. coli phosphonate-binding protein (EcPhnD) and potential cpFP insertion sites.

FIG. 5|Cartoon representation showing ligand bound Thermus thermophilus glucose binding protein (TtGBP) and potential cpFP insertion sites.

FIG. 6A-B|Changes in EcMBP upon maltose binding and locations at which circularly-permuted fluorescent protein (cpFP) was inserted are shown as colored spheres at the Cα positions. Yellow: 165-166, Green: 175-176, Cyan: 311-312, Violet: 317-318(A). (B) shows backbone structural changes. The Ca dihedral is calculated from the four atoms: Cαi+2, Cαi+1, Cαi, Cαi-1. ΔDihedral is calculated as the difference in dihedrals between the closed (1ANF) and open (1OMP) states of MBP, and corrected to fall within a range of −180° to 180°. The regions near residues 175 and 311 are labeled. There is a crystallographic artifact at the N-terminus resulting in the appearance of significant structural changes.

FIG. 7A|Amino acid sequence of MBP-165-cpGFP (SEQ ID NO:1).

FIG. 7B|Amino acid sequence of MBP-165-cpGFP.PPYF (SEQ ID NO:2).

FIG. 7C|Amino acid sequence of MBP-165-cpGFP.PCF (SEQ ID NO:3).

FIG. 8A|Amino acid sequence of MBP-175-cpGFP (SEQ ID NO:4).

FIG. 8B|Amino acid sequence of MBP-175-cpGFP.L1-HL (SEQ ID NO:5).

FIG. 9A|Amino acid sequence of MBP-311-cpGFP (SEQ ID NO:6).

FIG. 9B|Amino acid sequence of MBP-311-cpGFP.L2-NP (SEQ ID NO:7).

FIG. 10|Amino acid sequence of MBP-317-cpGFP (SEQ ID NO:8).

FIGS. 11A-11D|Line charts showing EcMBP plot of ΔF/F for clarified lysate screen of cpGFP linker-screens at insertion points 165, 175, 311, and 317. The horizontal dashed line at zero indicates no fluorescence change. Standard deviations in ΔF/F are less than 10% of an average ΔF (repetitions for MBP165-cpGFP.PPYF yields ΔF/F values of 2.51, 2.63, and 2.54).

FIG. 12|Isothermal titration calorimetry (ITC) of MBP317-cpGFP with maltose.

FIG. 13|Graph showing EcMBP165-cpGFP.PPYF affinity variant binding maltose-binding curves. Binding curves for affinity variants of MBP165-cpGFP.PPYF. Data is fit to a single-binding site isotherm. Curve-fit affinities are: WT binding pocket, 5 μM (●); W230A, 32 μM (▪); W62A, 375 μM (▴); W340A, >1 mM (▾); 1329W, 11 μM (□).

FIGS. 14A-14D|Line graphs showing maltose and sucrose binding curves for wild-type and 5-7 variants of the EcMBP-cpGFP sensors. Maltose (black) and sucrose (red) binding curves for wild-type (filled, solid lines) and 5-7 variants (open, dashed lines) of the MBP-cpGFP sensors. MBP165-cpGFP.PPYF (a); MBP165-cpGFP.PCF (b); MBP175-cpGFP.L1-HL (c); MBP311-cpGFP.L2-NP (d).

FIGS. 15A-15D|Line graphs showing emission spectra for colored variants of EcMBP sensors. Fluorescence emission spectra of the MBP165-Blue, Cyan, Green, and Yellow wild-type sensors (a) and the 5-7 variants (b) in the absence of ligand (dashed lines, open circles), with 10 mM maltose (solid lines, filled circles), or 10 mM sucrose (solid lines, filed squares). Sensors were excited at 383, 433, 485, and 485 nm, respectively. Titration of maltose and sucrose in the Blue, Cyan, Green, and Yellow MBP165 wild-type sensors (c) and for the 5-7 variants (d). Filled circles are titration of maltose, open circles are titration of sucrose. For the wild-type sensors, Kds for maltose binding are: Blue 3.3 μM, Cyan 13 μM, Green 4.5 μM, Yellow 3.3 μM. No sucrose binding is observed. For the 5-7 variants, Kd of Green is 2.4 mM (sucrose) and 7.1 mM (maltose). Kd of Yellow is 2.5 mM (sucrose) and 4.5 mM (maltose).

FIG. 16|Plot of ΔF/F for clarified lysate screen of MBP165-cpBFP linker-screen. The horizontal dashed line at zero indicates no fluorescence change.

FIGS. 17A-17B|Line graphs showing maltose binding. Blue (wt binding pocket) has an affinity of 2.7 μM. Green (W230A) has an affinity of 40 μM. Yellow (W62A) has an affinity of 350 μM. Cyan (W340A) has an affinity of approximately 1.7 mM. Data is plotted at ΔF/F (a) or normalized to Fractional Saturation (b).

FIGS. 18A-18C|Images bacterial cells expressing (a) EGFP, (b) PPYF, or (c) PPYF.T203V in the absence (top) and presence (bottom) of maltose.

FIGS. 19A-19B|Line graphs showing EcMBP-cpGFP.PPYF.T203V 2-photon excitation spectra. MBP165-cpAzurite.L2-FE (a), -cpCFP.PCF (a), -cpGFP.PPYF (b), and -cpYFP.PPYF (b) were excited at the wavelengths indicated and emission measured through appropriate wavelength filters. Two graphs are shown to present different y-axis scales. Optimal ΔF/F values for 2-photon excitation of the spectral variants of MBP165 are: -cpAzurite, 1.1 (ex 760 nm); -cpCFP, 2.3 (ex 830-960 nm); -cpGFP, 10.0 (ex 940 nm); -cpYFP, 2.6 (ex 940 nm).

FIGS. 20A-20C|Images showing EcMBP-cpGFP.PPYF.T203V expressing HEK cells. Images of individual HEK293 cells expressing membrane displayed PPYF.T203V in the absence of maltose (a), in the presence of 1 mM maltose (b), and after washout with maltose-free buffer (c). Scale bars are 10 μm.

FIGS. 21A-21B|Graphs showing quantification of fluorescence of EcMBP-cpGFP.PPYF.T203V when displayed on the surface of HEK cells. (a) Concentration dependence. (b) Observed fluorescence after a “puff” of HBSS solution containing 1 mM maltose and 2.5 nM Alexa Fluor® 568 (Invitrogen, Carlsbad, Calif.).

FIGS. 22A-22D|Cartoon representations and close-up views of inter-domain linkers and selected amino acids of the cpGFP chromophore environment of the structure of MBP175-cpGFP.L1-HL (A and B) and MBP311-cpGFP.L2-NP (C and D) bound to maltose. The MBP domain is colored as in FIG. 1. The cpGFP domain is green and the inter-domain linkers are colored white. The cpGFP chromophore is displayed as sticks and the bound maltose as red and white spheres. Ordered water molecules are represented as red spheres. Selected hydrogen bonds are displayed as dashed black lines. β-strands 10 and 11 of cpGFP are displayed as semi-transparent for clarity. The 2Fo-Fc electron density map calculated with the displayed residues omitted from the model is shown as blue mesh.

FIGS. 23A-23D|EcMBP-cpGFP: effect of T203V mutation on fluorescence. (a) Emission spectra of 1 μM purified eGFP (filled circles), cpGFP (filled squares), MBP165-cpGFP.PPYF (open circles), and MBP165-cpGFP.PPYF+T203V (open squares) in the absence (dashed lines) or presence (solid lines) of 1 mM maltose. cpGFP is half as bright as eGFP, and the saturated MBP165-cpGFP.PPYF variants are about half as bright as cpGFP. (b) Titration of maltose for MBP165-cpGFP.PPYF (filled squares), and MBP165-cpGFP.PPYF+T203V (filled circles). Affinities for each protein are the same, but with different ΔF/F. (c) Emission spectra of 1 μM purified eGFP (filled circles), cpGFP (filled squares), MBP311-cpGFP.L2-NP (open circles), and MBP311-cpGFP.L2-NP+T203V (open squares) in the absence (dashed lines) or presence (solid lines) of 1 mM maltose. Note that mutation T203V decreases the fluorescence of both the apo-state and the saturated state of MBP311-cpGFP.L2-NP. (d) Titration of maltose for MBP311-cpGFP.L2-NP (filled squares), and MBP311-cpGFP.L2-NP+T203V (filled circles). Affinities for each protein are the same, but with ΔF/F slightly increased for the T203V variant.

FIG. 24A|Amino acid sequence of PfMBP171-cpGFP (SEQ ID NO:50)

FIG. 24B|Amino acid sequence of PfMBP171cpGFP.L2-FE (SEQ ID NO:51)

FIG. 25A|Amino acid sequence of PfMBP316-cpGFP (SEQ ID NO:52)

FIG. 25B|Amino acid sequence of PfMBP316-cpGFP.L1-NP (SEQ ID NO:53)

FIG. 26A-26B|Plot of ΔF/F for clarified lysate screen of cpGFP linker-screens at insertion points 171 (A) and 316 (B).

FIGS. 27A-27D|Plot of Beta-sheet circular dichroism (CD) signal as a function of temperature.

FIGS. 28A-28B|PfMBP Fluorescence vs. temperature. (A) Plot of fluorescence as a function of temperature in the presence (solid) or absence (dashed) of ligand. (B) Plot of ΔF/F as a function of temperature. Using the data from panel (a), ΔF/F for each protein (Fbound-Fapo/Fapo) was calculated for each temperature.

FIGS. 28C-28E|Line graphs showing the function of immobilized and soluble proteins.

FIG. 29A|Amino acid sequence of EcYbeJ253-cpGFP (SEQ ID NO:62).

FIG. 29B|Amino acid sequence of EcYbeJ253-cpGFP.L1LVL2NP (SEQ ID NO:63).

FIG. 30|EcYbeJ binding curves. Plot of ΔF/F as a function of [Glutamate], μM. The first generation sensor, EcYbeJ253.L1-LV (with the A184V) mutation (grey, solid) has an affinity for glutamate of about 100 μM and a ΔF/F of 1.2. The reversion of that affinity mutation, V184A, in the L1-LV background increases affinity to 1 μM (grey dashed). The second generation sensor, with the L2-NP linker optimization and the A184V mutation, has a ΔF/F of at least 4 and an affinity for glutamate of about 100 μM (black solid).

FIG. 31|EcYbeJ Hema/cMyc analysis. The effect of N- and C-terminal tags on ΔF/F and glutamate affinity were determined by expressing variously tagged versions of the EcYbeJ253.L1LVL2NP protein in bacteria. The presence of the pRSET leader sequence (black) has no effect on ΔF/F (˜5) or affinity (˜120 μM), when compared to the version without a tag (grey). The addition of the cMyc tag to the C-terminus retains ΔF/F and increases affinity slightly, to 60 μM. The addition of the N-terminal hemagglutinin tag, with (green) or without (orange) the cMyc tag, decreases ΔF/F substantially.

FIGS. 32A-32B|EcYbeJ253-cpGFP.L1LVL2NP.pMinDis expressed in HEK293 cells. (A) Images of the sensor expressing HEK cells in the absence of glutamate (left), with 100 μM glutamate (center), and re-imaged after wash-out of glutamate with buffer (right). (B) By measuring the equilibrium ΔF/F with different concentrations of glutamate in the buffer, an in situ binding affinity (black) can be obtained. The surface displayed sensor has a higher affinity (3 μM) for glutamate than the soluble sensor (grey), which is about 90 μM.

FIG. 33|EcYbeJ253-cpGFP.L1LVL2NP.pMinDis expressed in neuronal culture, and responds rapidly to added glutamate (green). Red shows signal of 2.5 nM Alexa Fluor® 568 (Invitrogen, Carlsbad, Calif.), also in pipette.

FIG. 34A|Amino acid sequence of EcPhnD90-cpGFP (SEQ ID NO:77).

FIG. 34B|Amino acid sequence of EcPhnD90-cpGFP.L1AD+L297R+L301R (SEQ ID NO: 78).

FIGS. 35A-35C|EcPhnD90-cpGFP Binding Curves. For both the L1AD and the L1AD+L297R+L301R variants, binding was determined for (A) 2-aminoethylphosphonate (2AEP), (B) methylphosphonate (MP), and (C) ethylphosphonate (EP).

FIGS. 36A-36C|The crystal structures of the ligand-free (A), open state (with H157A mutation to the binding pocket) and the ligand-bound (B), closed state of EcPhnD clearly shows a large conformational change. Residues in between which cpGFP is inserted in EcPhnD90-cpGFP are marked by red spheres, in the equatorial strand (red). (C) Analysis of the change in Cα dihedral (ΔDihedral) clearly shows that residues for which there is the greatest ΔDihedral upon going from the open to the closed state are residues 88 (ΔDihedral=−75°), 89 (ΔDihedral=123°), and 90 (ΔDihedral=52°).

FIG. 37A|Amino acid sequence of TtGBP326-cpGFP (SEQ ID NO:91).

FIG. 37B|Amino acid sequence of TtGBP326.L1-PA (SEQ ID NO:92).

FIG. 37C|Amino acid sequence of TtGBP326.H66A (SEQ ID NO:93).

FIG. 37D|Amino acid sequence of TtGBP326.H348A (SEQ ID NO:94).

FIG. 38|TtGBP326-cpGFP Binding Curves. Plot of ΔF/F as a function of [Glucose], mM.

FIG. 39|An image showing TtGBP326-cpGFP expressed as a transgenic reporter of intracellular glucose in cultured human cells.

FIGS. 40A-40B|Are line graphs showing that the addition of extracellular glucose increases TtGBP326-cpGFP fluorescence in human cells.

FIG. 41|Amino acid sequence of Escherichia coli maltodextrin-binding protein (EcMBP) (SEQ ID NO: 105).

FIG. 42|Amino acid sequence of Pyrococcus furiosus maltose-binding protein (PfMBP) (SEQ ID NO: 106).

FIG. 43|Amino acid sequence of E. coli glutamate-binding protein (EcYbeJ) (SEQ ID NO:107).

FIG. 44|Amino acid sequence of E. coli phosphonate-binding protein (EcPhnD) (SEQ ID NO:108).

FIG. 45|Amino acid sequence of Thermus thermophilus glucose-binding protein (TtGBP) (SEQ ID NO:109).

FIG. 46|Amino acid sequence of UniProt accession number Q92N37 (SEQ ID NO: 110).

FIG. 47|Amino acid sequence of UniProt accession number DOVWX8 (SEQ ID NO:111).

FIG. 48|Amino acid sequence of UniProt accession number Q7CX36 (SEQ ID NO:112).

FIG. 49|Amino acid sequence of UniProt accession number POAD96 (SEQ ID NO:113).

FIG. 50|Amino acid sequence of TtGBP326.L1PA.L2NP.H66A.H348A.L276V (SEQ ID NO:114).

FIG. 51|A line graph showing binding of TtGBP326.L1PA.L2NP.H66A.H348A.L276V to glucose.

FIG. 52|A line graph showing fluorescence increase upon addition of glucose to HEK293 cells expressing TtGBP326.LIPA.L2NP.H66A.H348A.L276V on their extracellular surface.

FIG. 53|A schematic of Structure I as described herein.

DETAILED DESCRIPTION

The present disclosure is based, at least in part, on the discovery of structures and methods related to and useful for genetically encoded biosensors. Specifically, the disclosure provides genetically encoded recombinant or chimeric peptides for use as biosensors and methods for the design, production, and use of such biosensors. As described below, these sensors can be employed (e.g., expressed) in biological systems to detect and/or monitor a wide range of target analytes (e.g., a defined, selected, and/or specific analytes) due, in part, to the signal change generated by the sensors upon binding to their respective analyte(s), which signal change allows bound and unbound sensors to be distinguished.

While the disclosure encompasses generic biosensors and methods related thereto, examples of particular binding sensors, including biosensors for detecting maltose, sucrose, maltotriose, glutamate, phosphonate, and glucose are also disclosed.

Compositions

Provided herein are genetically encoded biosensors, i.e., nucleic acids encoding peptides, and/or the encoded peptides (e.g., isolated peptides), for use as biosensors. Biosensors herein include genetically encoded recombinant peptides containing an analyte-binding framework portion linked (e.g., operably linked) to at least one independent signaling portion, wherein the independent signaling portion is allosterically modulated or regulated by the framework portion upon interaction of the framework portion with an analyte (e.g., a defined, selected, and/or specific analyte), such that signaling from the signaling portions is altered upon interaction of the framework portion with the analyte.

In some instances, an independent signaling portion is present at a site within the framework portion that undergoes a conformational change upon interaction of the framework portion with an analyte such that the conformational change allosterically modulates or regulates signaling by the signaling portion. For example, biosensors herein can include structure I (FIG. 53).

As described herein, he signaling portion is present at a site within the framework portion that undergoes a conformational change upon interaction of the framework portion with an analyte.

In some instances, signaling by the signaling portion is detectably altered upon interaction (e.g., binding) of the framework portion with an analyte. For example, signaling by the signaling portion can detectably increase or detectably decrease upon interaction (e.g., binding) of the framework portion with an analyte. In some cases, biosensors have a signal change upon binding (e.g., specific binding) to their respective analyte of at least about, for example, ±0.5, and/or an increase or decrease in signal of at least about, for example, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 100%, 250%, 500%, 750%, 1000%, or more than 1000%, e.g., relative to unbound biosensor. In some increases, the level of signal change is linked to background signal. Values represented here can be converted and/or expressed into any conventional units using ordinary skill. For example, units can be expressed as ‘signal change’ (as used above), ΔF/F and/or as signal-to-noise ratio (e.g., ΔF/F multiplied by the square root of the number of photons collected). In some instances, signaling by a biosensor can be intensity based.

In some instances, biosensors herein are distinguishable from Förster resonance energy transfer, also known as fluorescence resonance energy transfer (FRET)-based sensors, which require donor and acceptor chromophores, e.g., that function in concert, in that they include independently functioning or detectable signaling portions. For example, in some instances, signaling by a first signaling portion of a biosensor herein is independent of signaling by a second signaling portion within the same or a distinct biosensor. As noted above, signaling portions are allosterically regulated by the framework portion to which they are linked upon interaction of the framework portion with an analyte (e.g., a defined, selected, and/or specific analyte).

Framework Portions

Framework portions include genetically encoded macromolecules (e.g., proteins or peptides) that undergo conformational alteration (e.g., a structural change) upon interaction (e.g., binding) with, or to, an analyte (e.g., an analyte-binding dependent conformational alteration). For example, genetically encoded framework portions can have a first structure in the absence of an analyte (e.g., in an unbound or open state) and a second structure, that is detectably distinct (e.g., differences in structures before and after a conformational change can be observed using methods known in the art) from the first structure, in the presence of an analyte (e.g., in a bound or closed state), e.g., under physiologic conditions. In some instances, the conformational change that occurs upon interaction with an analyte (e.g., an analyte-binding dependent conformational alteration) is detectably distinct (e.g., can be observed using methods known in the art) from a conformational change that may occur for the same protein or peptide under other physiological conditions (e.g., a change in conformation induced by altered temperature, pH, voltage, ion concentration, phosphorylation).

Methods for identifying proteins or peptides that exhibit suitable conformational characteristics and/or for observing differences in structure between structures or before and after a conformational change are known in the art and/or are described herein. Such methods can include, for example, one or more of structural analysis, crystallography, NMR, EPR using Spin label techniques, Circular Dichroism (CD), Hydrogen Exchange surface Plasmon resonance, calorimetry, and/or FRET.

In some instances, framework portions can have a first structure in the absence of an analyte (e.g., in an unbound or open state) and a second structure, that is detectably distinct (e.g., can be observed using methods known in the art) from the first structure, in the presence of an analyte (e.g., in a bound or closed state), e.g., under physiologic conditions, wherein the structural change between the open and closed state can allosterically modulate an independent signaling portion recombinantly (e.g., artificially introduced) present within the framework portion (see, e.g., Structure I in FIG. 53).

Framework portions can also interact (e.g., bind) with at least one analyte (e.g., at least one defined, specific, and/or selected analyte). In some instances, a framework portion can interact specifically with one analyte (e.g., at least one defined, specific, and/or selected analyte). In such cases, affinity of binding between the framework binding peptide and the analyte can be high or can be controlled (e.g., with millimolar, micromolar, nanomolar, or picomolar affinity). Alternatively, the single framework binding protein can bind two or more analytes (e.g., two or more defined, specific, and/or selected analytes). In such cases, affinity of binding to the two or more analytes can be the same or distinct. For example, the affinity of binding can be greater for one analyte than it is for a second or third, etc., analyte. In some instances, binding between a framework portion and an analyte (e.g., at least one defined, specific, and/or selected analyte) have an affinity of for example, 10 mM to 1 pM.

As used herein, the term “analyte” can include naturally occurring and/or synthetic sugars, amino acids, proteins (e.g., proteins, peptides, and/or antibodies), hormones, ligands, chemicals (e.g., small molecules), pharmaceuticals, nucleic acids, cells, tissues, and combinations thereof.

In some instances, biosensors can include one, two, or more framework binding portions that bind (e.g., binds specifically) a single analyte (e.g., a single defined, specific, and/or selected analyte) or distinct analytes (e.g., two or more distinct defined, specific and/or selected analytes). Alternatively or in addition, the framework portion can be chimeric. In such cases, a first part of the framework portion can be a first peptide or can be derived from a first peptide, and a second part of the framework portion can be a second peptide or can be derived from a second peptide, wherein the first a second peptides are combined to result in a single peptide.

Accordingly, framework portions can include macromolecules that undergo a conformational change upon interaction with an analyte. One non-limiting example of a suitable macromolecule is Calmodulin (CaM). CaM is in an extended shape in the absence of Ca²⁺ and in a condensed conformation in the presence of Ca²⁺ (Kuboniwa et al., Nat. Struc. Biol., 2:768-776, 1996 and Fallon and Quiocho, Structure, 11:1303-1307, 2003).

In some instances, a framework binding portion can be a bacterial protein or can be derived from a bacterial protein. Suitable bacterial proteins can include, but are not limited to, for example, periplasmic binding proteins (PBPs).

PBPs from bacteria are generally useful in the biosensors herein at least because they undergo dramatic conformational changes upon ligand binding (Ouiocho et al. Mol. Microbiol., 20:17-225, 1996). X-ray crystal structures of the apo (open) and bound (closed) forms of various PBPs reveal that these proteins have two (typically, although some have more) domains that undergo a large hinge-twist movement relative to each other in a Venus flytrap manner (Dwyer and Hellinga, Curr. Opin. Struc. Biol., 14:495-504, 2004). This conformational change has been exploited to create a number of FRET-based genetically encoded sensors (see, e.g., Deuschle et al., Pro. Sci, 14:2304-2314, 2005; Deuschle et al., Cytometry, 64:3-9, 2005; Okumoto et al., Proc. Natl. Acad. Sci. USA., 102:8740-8745, 2005; Bogner and Ludewig, J. Fluoresc., 17:350-360, 2007; and Gu et al., FEBS Letters, 580:5885-5893, 2006). In addition, the ligand-binding diversity of the PBP superfamily is large (Dwyer and Hellinga, Curr. Opin. Struc. Biol., 14:495-504, 2004).

In some instances, framework portions can include, for example, one or more of: arabinose-binding protein(s), glucose/galactose-binding protein(s), histidine-binding protein(s), maltose-binding protein(s), glutamine-binding protein(s), maltotriose-binding protein(s), RBP, ribose-binding protein(s), acetylcholine binding protein(s), choline binding protein(s), lysine binding protein(s), arginine binding protein(s), gamma aminobutyric acid (GABA) binding protein(s), ion-binding protein(s), peptide-binding protein(s), lactate-binding protein(s), histamine-binding protein(s), and/or

Leucine/Isoleucine/Valine binding protein(s), including full length proteins, fragments, and/or variants thereof.

In some instances, exemplary framework portions can include: SEQ ID NO:105, which is Escherichia coli maltodextrin-binding protein (EcMBP) (UniProt accession number POAEX9); SEQ ID NO: 106, which is Pyrococcus Furiosus maltotriose-binding protein (PfMBP) (UniProt accession number P58300); SEQ ID NO:107, which is E. coli glutamate-binding protein (EcYbeJ) (UniProt accession number Q1R3F7); SEQ ID NO:108, which is E. coli phosphonate-binding protein (EcPhnD) (UniProt accession number P37902); and/or SEQ ID NO:109, which is Thermus thermophilus glucose-binding protein (TtGBP) (UniProt accession number Q72KX2, including full length proteins, fragments, and/or variants thereof.

In some instances, exemplary framework portions can include SEQ ID NO: 110 (UniProt accession number Q92N37); SEQ ID NO:111 (UniProt accession number D0VWx8, SEQ ID NO:112 (UniProt accession number Q7CX36), and/or SEQ ID NO:113 (UniProt accession number POAD96, including full length proteins, fragments, and/or variants thereof.

In some instances, framework portions, or biosensors, do not include signal peptides, or portions of signal peptides, that would otherwise be present in the peptide from which the framework portion is derived.

Signaling Portions

Biosensors herein include one or more genetically encoded signaling portions (e.g., independent signaling portions) within the amino acid sequence of a framework portion at a site(s) within the framework portion that undergo(es) a conformational change upon interaction of the framework portion with an analyte (e.g., a defined, specific, and/or selected analyte).

Signaling portions (e.g., independent signaling portions) include genetically encoded molecules (e.g., peptides or proteins) that can be allosterically induced to emit a detectable signal (e.g., an analyte-binding dependent signal).

In some instances, the detectable signal is detectably distinct (e.g., can be distinguished using methods known in the art and/or disclosed herein) from a signal emitted by the molecule prior to allosteric inducement (e.g., signaling portions can emit a detectable signal in two detectably distinct states. For example, first signal can be emitted in unbound state and a second signal can be emitted in bound state). As noted above, in some instances, the detectable signal is proportional to the degree of allosteric inducement. In some instances, if two or more signaling portions are present in a biosensor, then two or more detectably distinct signals can be emitted by the biosensor.

In some instances, a genetically encoded independent signaling portion is a genetically encoded fluorescent protein (FP), e.g., a macromolecule containing a functional group (e.g., a fluorophore) that absorbs energy of a specific wavelength and re-emits energy at a different (but equally specific) wavelength, including, for example, circularly permuted FP (cpFP).

As used herein, the term “fluorophore” relates to a functional group in a molecule which will absorb energy of a specific wavelength and re-emit energy at a different (but equally specific) wavelength. In some instances, fluorophore containing molecules include fluorescent proteins. The fluorophore in green fluorescent protein (GFP) includes Ser-Tyr-Gly sequence (i.e., Ser65-dehydroTyr66-Gly67), which is post-translationally modified to a 4-(p-hydroxybenzylidene)-imidazolidin-5. Exemplary genetically encoded fluorescent proteins include, but are not limited to, fluorescent proteins from coelenterate marine organisms, e.g., Aequorea victoria, Trachyphyllia geoffroyi, coral of the Discosoma genus, Rennilla mulleri, Anemonia sulcata, Heteractis crispa, Entacmaea quadricolor, and/or GFP (including the variants S65T and EGFP, Rennilla mulleri GFP), cyan fluorescent protein (CFP), including Cerulean, and mCerulean3 (described by Markwardt et al., PLoS ONE, 6(3) e17896.doi:10.1371/journal.pone.0017896), CGFP (CFP with Thr203Tyr: Has an excitation and emission wavelength that is intermediate between CFP and EGFP), yellow fluorescent protein (YFP, e.g., GFP-Ser65Gly/Ser72Ala/Thr203Tyr; YFP (e.g., GFP-Ser65Gly/Ser72Ala/Thr203Tyr) with Va168Leu/Gln69Lys); Citrine (i.e., YFP-Va168Leu/Gln69Met), Venus (i.e., YFP-Phe46Leu/Phe64Leu/Met153Thr/Val163Ala/Ser175Gly), PA-GFP (i.e., GFP-Val/163Ala/Thr203His), Kaede), red fluorescent protein (RFP, e.g., long wavelength fluorescent protein, e.g., DsRed (DsRed1, DsRed2, DsRed-Express, mRFP1, drFP583, dsFP593, asFP595), eqFP611, and/or other fluorescent proteins known in the art (see, e.g., Zhang et al., Nature Reviews, Molecular and Cellular Biology, 3:906-908, 2002).

As set forth above, in some instances, fluorophore containing molecules include fluorescent proteins that can be or that are circularly permutated. Circular permutation methods are known in the art (see, e.g., Baird et al., Proc. Natl. Acad. Sci., 96:11241-11246, 1999; Topell and Glockshuber, Methods in Molecular Biology, 183:31-48, 2002).

In some instances, single-FP sensors have a number of advantages: they preserve spectral bandwidth for multi-analyte imaging; their saturated states may be nearly as bright as the parental FP, and their ligand-free states may be arbitrarily dim, providing large theoretical fluorescence increases. This allows for much greater changes in fluorescence and thus increased signal-to-noise ratios and greater resistance to photobleaching artifacts (Tian et al., Nat. Methods, 6:875-881, 2009).

In some instances, issues arising from long-term effects such as gene regulation and protein expression and degradation can be identified by simply fusing the intensity-based sensor to a another fluorescent protein of different color, to serve as a reference channel.

In some instances, biosensors can include circularly permuted YFP (cpYFP) as a cpFP. cpYFP has been used as a reporter element in the creation of sensors for H2O2 (HyPer) (Belousov et al., Nat. Methods, 3:281-286, 2006), cGMP (FlincG) (Nausch et al., Proc. Natl. Acad. Sci. USA., 105:365-370, 2008), ATP:ADP ratio (Perceval) (Berg et al., Nat. Methods., 105:365-370, 2008), and calcium ions (Nakai et al., Nat. Biotechno., 19:137-141, 2001), including full length, fragments, and/or variants thereof.

Linker Portions

As shown in Structure I (FIG. 53), biosensors herein can optionally include one or more genetically encoded linkers positioned between or operably linking the framework portion and the signaling portion. Linker portions can include at least one naturally occurring or synthetic amino acid (discussed below) as exemplified by SEQ ID NOs: 9-49, 54-61, 64-76, 79-90, 95-104. In some instances, linker can include one or more of SEQ ID NOs: 9-49, 54-61, 64-76, 79-90, 95-104, and/or portions of SEQ ID NOs: 9-49, 54-61, 64-76, 79-90, 95-104. For example, linkers can include, but are not limited to, one or more of: PxSHNVY (SEQ ID NO:114), xPSHNVY (SEQ ID NO:115), xxSHNVY (SEQ ID NO:116), xxSHNVF (SEQ ID NO:117), PxSHNVF (SEQ ID NO:118), PxSYNVF (SEQ ID NO:119), xxSYNVF (SEQ ID NO:120), PxSYNVF (SEQ ID NO:121), xxSYNVF (SEQ ID NO:122), PxSxNVY (SEQ ID NO:123), PxSHxVY (SEQ ID NO:124), PxSHNxY (SEQ ID NO:125), PxSHNVx (SEQ ID NO:126), FNxxY (SEQ ID NO:127), FNxY (SEQ ID NO:128), FNY (SEQ ID NO:129), FxY (SEQ ID NO:130), xxY (SEQ ID NO:131), WxY (SEQ ID NO:132), xKY, (SEQ ID NO:133), FNPxY (SEQ ID NO:134), FNxPY (SEQ ID NO:135), HNS (SEQ ID NO:136), GGS (SEQ ID NO:137), xxS (SEQ ID NO:138), xxK (SEQ ID NO:139), GGK (SEQ ID NO:140), PXS (SEQ ID NO:141), xPS (SEQ ID NO:142), Px (SEQ ID NO:143), xP (SEQ ID NO:144), IxxS (SEQ ID NO:145), NxPK (SEQ ID NO:146), NPcK (SEQ ID NO:147), PPxSH (SEQ ID NO:148), PPxxSH (SEQ ID NO:149), PPPxSH (SEQ ID NO:150), PPxPSH (SEQ ID NO:151), xxSH (SEQ ID NO:152), PPxx (SEQ ID NO:153), FNxKN (SEQ ID NO:154), FNxxKN (SEQ ID NO:155), FNxPKN (SEQ ID NO:156), FNPxKN (SEQ ID NO:157), FNxx (SEQ ID NO:158), N, ADGSSH (SEQ ID NO:159), ADxxSH (SEQ ID NO:160), ADxPSH (SEQ ID NO:161), ADPxSH (SEQ ID NO:162), ADxx (SEQ ID NO:163), ADxxSH (SEQ ID NO:164), FNPG (SEQ ID NO:165), FNxxPG (SEQ ID NO:166), xxPG (SEQ ID NO:167), FNxx (SEQ ID NO:168), FNPx (SEQ ID NO:169), KYxxSH (SEQ ID NO:170), KYPxSH (SEQ ID NO:171), KYxPSH (SEQ ID NO:172), FxxP (SEQ ID NO:173), FNxP (SEQ ID NO:174), and/or FNPx (SEQ ID NO:175), where “x” indicates any amino acid.

Exemplary Biosensor Constructs

As noted above, biosensors herein include genetically encoded biosensors, i.e., nucleic acids encoding biosensors, and/or the encoded biosensors (e.g., isolated biosensors), for use as biosensors. In some instances, nucleic acids encoding biosensors include isolated nucleic acids. In some instances, the portion of a nucleic acid encoding a biosensor can include a single reading frame encoding the biosensor. For example, a biosensor can be encoded by a portion of a nucleic acid that falls within a start codon and a stop codon. In some instances, biosensors are isolated (e.g., biosensors are substantially free of contaminating and/or non-biosensor components).

In some instances, biosensors can include, for example, one or more framework portions selected from the group consisting of: arabinose-binding protein(s), glucose/galactose-binding protein(s), histidine-binding protein(s), maltose-binding protein(s), maltotriose-binding protein(s), glutamine-binding protein(s), RBP, ribose-binding protein(s), acetylcholine binding protein(s), choline binding protein(s), lysine binding protein(s), arginine binding protein(s), gamma aminobutyric acid (GABA) binding protein(s), ion-binding protein(s), peptide-binding protein(s), lactate-binding protein(s), histamine-binding protein(s), and/or Leucine/Isoleucine/Valine binding protein(s), including full length proteins, fragments, and/or variants thereof, including full length proteins, fragments and/or variants thereof, and at least one independent signaling portion present at a site within the framework portion that undergoes a conformational change upon interaction of the framework portion with an analyte.

In some instances, biosensors can include, for example, one or more framework portions selected from the group consisting of: SEQ ID NO:105, which is Escherichia coli maltodextrin-binding protein (EcMBP) (UniProt accession number POAEX9); SEQ ID NO: 106, which is Pyrococcus Furiosus maltose-binding protein (PfMBP) (UniProt accession number P58300); SEQ ID NO:107, which is E. coli glutamate-binding protein (EcYbeJ) (UniProt accession number Q1R3F7); SEQ ID NO:108, which is E. coli phosphonate-binding protein (EcPhnD) (UniProt accession number P37902); and/or SEQ ID NO:109, which is Thermus thermophilus glucose-binding protein (TtGBP) (UniProt accession number Q72KX2), including full length proteins, fragments and/or variants thereof, and at least one independent signaling portion present at a site within the framework portion that undergoes a conformational change upon interaction of the framework portion with an analyte.

In some instances, biosensors can include, for example, one or more framework portions selected from the group consisting of: SEQ ID NO: 110 (UniProt accession number Q92N37); SEQ ID NO:111 (UniProt accession number D0VWx8, SEQ ID NO:112 (UniProt accession number Q7CX36), and/or SEQ ID NO:113 (UniProt accession number POAD96), including full length proteins, fragments and/or variants thereof, and at least one independent signaling portion present at a site within the framework portion that undergoes a conformational change upon interaction of the framework portion with an analyte.

In some instances, biosensors include any one or more: Maltose biosensors SEQ ID NOs: 1-8 (i.e., Escherichia coli maltodextrin-binding protein (EcMBP)) or SEQ ID NOs: 50-53 (Pyrococcus Furiosus maltose-binding protein (PfMBP)), including full length proteins, fragments and/or variants thereof;

Glutamate biosensors SEQ ID NOs: 62-63 (E. coli glutamate-binding protein (EcYbeJ)), including full length proteins, fragments and/or variants thereof;

Phosphonate biosensors SEQ ID NOs: 77-78 (E. coli phosphonate-binding protein (EcPhnD)), including full length proteins, fragments and/or variants thereof; and/or

Glucose biosensors SEQ ID NOs: 91-94 (Thermus thermophilus glucose-binding protein (TtGBP)), including full length proteins, fragments and/or variants thereof.

In some instances, nucleic acids encoding and/or amino acid sequences of any of the framework portions, signaling portions, linker portions, or biosensors (e.g., SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) (e.g., any amino acid sequence) disclosed herein can be modified to generate fragments (e.g., truncated peptides) and/or variants (e.g., peptides with a defined sequence homology to the peptides disclosed herein). Variants can include framework portions, signaling portions, linker portions, or biosensors with amino acid sequences with homology to the framework portions, signaling portions, linker portions, or biosensors disclosed herein and/or truncated forms of the framework portions, signaling portions, linker portions, or biosensors herein. In some instances, truncated forms of the framework portions, signaling portions, linker portions, or biosensors herein can include 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 50-100, 101-150, fewer amino acids than the framework portions, signaling portions, linker portions, and/or biosensors herein, e.g., wherein the truncated biosensor variants retain at least at portion of the binding and/or signaling properties of same biosensor without truncation (e.g., at least 50%, 60%, 70%, 80%, 90%, or 100% of the binding and/or signaling properties of the same biosensor without truncation). In addition, truncations can be made at the amino-terminus, the carboxy-terminus, and/or within the body of the framework portions, signaling portions, linker portions, and/or biosensors herein.

While variants are generally observed and discussed at the amino acid level, the actual modifications are typically introduced or performed at the nucleic acid level. For example, variants with 95%, 96%, 97%, 98, or 99% sequence identity to SEQ ID NOs:91, 92, 93, and/or 94 can be generated by modifying the nucleic acids encoding SEQ ID NOs: 91, 92, 93, and/or 94 using techniques (e.g., cloning techniques) known in the art and/or that are disclosed herein.

As with all peptides, polypeptides, and proteins, including fragments thereof, it is understood that modifications to the amino acid sequence can occur that do not alter the nature or function of the peptides, polypeptides, or proteins. Such modifications include conservative amino acids substitutions and are discussed in greater detail below.

The peptides, polypeptides, and proteins, including fragments thereof, provided herein are biosensors whose activity can be tested or verified, for example, using the in vitro and/or in vivo assays described herein.

In some instances, any of the framework portions, signaling portions, or biosensors (e.g., SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) (e.g., any amino acid sequence) described herein can be modified and varied so long as their desired function is maintained. For example, the polypeptides can be modified as long as the resulting variant polypeptides have the same or better characteristics as the polypeptide from which they derived. For example, the variants can have the same or better affinity for their respective analyte.

In some instances, the interacting face of a modified peptide can be the same (e.g., substantially the same) as an unmodified peptide (methods for identifying the interacting face of a peptide are known in the art (Gong et al., BMC: Bioinformatics, 6:1471-2105 (2007); Andrade and Wei et al., Pure and Appl. Chem., 64(11):1777-1781 (1992); Choi et al., Proteins: Structure, Function, and Bioinformatics, 77(1):14-25 (2009); Park et al., BMC: and Bioinformatics, 10:1471-2105 (2009)), e.g., to maintain binding to an analyte. Alternatively, amino acids within the interacting face can be modified, e.g., to decrease binding to an analyte and/or to change analyte specificity.

The interacting face of a peptide is the region of the peptide that interacts or associates with other molecules (e.g., other proteins). Generally, amino acids within the interacting face are naturally more highly conserved than those amino acids located outside the interacting face or interface regions of a protein. In some instances, an amino acid within the interacting face region of any of the framework portions or biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) (e.g., any amino acid sequence) disclosed herein can be the same as the amino acid shown in any of the framework portions or biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) (e.g., any amino acid sequence) disclosed herein or can be include conservative amino acid substitutions. In some instances, an amino acid within the interacting face region any of the framework portions or biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) (e.g., any amino acid sequence) disclosed herein can be substituted with an amino acid that increases the interaction between the framework portion or biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) (e.g., any amino acid sequence) and an analyte.

In some instances, genetically encoded biosensors can include peptides that have at least 80, 85, 90, 95, 96, 97, 98, 99 percent identity to the framework portions, signaling portions, or biosensors (e.g., SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) (e.g., any amino acid sequence) described herein. Those of skill in the art readily understand how to determine the identity of two polypeptides. For example, the identity can be calculated after aligning the two sequences so that the identity is at its highest level.

Another way of calculating identity can be performed by published algorithms. Optimal alignment of sequences for comparison may be conducted by the local identity algorithm of Smith and Waterman, Adv. Appl. Math, 2:482 (1981), by the identity alignment algorithm of Needleman and Wunsch, J. Mol. Biol. 48:443 (1970), by the search for similarity method of Pearson and Lipman, Proc. Natl. Acad. Sci. USA 85:2444 (1988), by computerized implementations of these algorithms (GAP, BESTFIT, FASTA, and TFASTA in the Wisconsin Genetics Software Package, Genetics Computer Group, 575 Science Dr., Madison, Wis.), or by inspection.

The same types of identity can be obtained for nucleic acids by, for example, the algorithms disclosed in Zuker, Science 244:48-52 (1989); Jaeger et al., Proc. Natl. Acad. Sci. USA 86:7706-10 (1989); Jaeger et al., Methods Enzymol. 183:281-306 (1989), which are herein incorporated by reference for at least material related to nucleic acid alignment. It is understood that any of the methods typically can be used and that in certain instances the results of these various methods may differ, but the skilled artisan understands if identity is found with at least one of these methods, the sequences would be said to have the stated identity and to be disclosed herein.

Amino acid sequence modifications typically fall into one or more of three classes: substitutional, insertional, or deletional modifications. Insertions include amino and/or terminal fusions as well as intra-sequence insertions of single or multiple amino acid residues. Insertions ordinarily will be smaller insertions than those of amino or carboxyl terminal fusions, for example, on the order of one to four residues. Deletions are characterized by the removal of one or more amino acid residues from the protein sequence. Typically, no more than about from 2 to 6 residues are deleted at any one site within the protein molecule. Amino acid substitutions are typically of single residues, but can occur at a number of different locations at once; insertions usually will be on the order of about from 1 to 10 amino acid residues; and deletions will range about from 1 to 30 residues. Deletions or insertions can be made in adjacent pairs, i.e., a deletion of 2 residues or insertion of 2 residues. Substitutions, deletions, insertions or any combination thereof may be combined to arrive at a final construct. The mutations must not place the sequence out of reading frame and preferably will not create complementary regions that could produce secondary mRNA structure. Substitutional modifications are those in which at least one residue has been removed and a different residue inserted in its place. In some instances, substitutions can be conservative amino acid substitutions. In some instances, variants herein can include one or more conservative amino acid substitutions. For example, variants can include 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 20-30, 30-40, or 40-50 conservative amino acid substitutions. Alternatively, variants can include 50 or fewer, 40 or fewer, 30 or fewer, 20 or fewer, 10 or fewer, 9 or fewer, 8 or fewer, 7 or fewer, 6 or fewer, 5 or fewer, 4 or fewer, 3 or fewer, or 2 or fewer conservative amino acid substitutions. Such substitutions generally are made in accordance with the following Table 1 and are referred to as conservative substitutions. Methods for predicting tolerance to protein modification are known in the art (see, e.g., Guo et al., Proc. Natl. Acad. Sci., USA, 101(25):9205-9210 (2004)).

TABLE 1 Conservative Amino Acid Substitutions Amino Acid Substitutions (others are known in the art) Ala Ser, Gly, Cys Arg Lys, Gln, His Asn Gln, His, Glu, Asp Asp Glu, Asn, Gln Cys Ser, Met, Thr Gln Asn, Lys, Glu, Asp, Arg Glu Asp, Asn, Gln Gly Pro, Ala, Ser His Asn, Gln, Lys Ile Leu, Val, Met, Ala Leu Ile, Val, Met, Ala Lys Arg, Gln, His Met Leu, Ile, Val, Ala, Phe Phe Met, Leu, Tyr, Trp, His Ser Thr, Cys, Ala Thr Ser, Val, Ala Trp Tyr, Phe Tyr Trp, Phe, His Val Ile, Leu, Met, Ala, Thr

In some instances, substitutions are not conservative. For example, an amino acid can be replaced with an amino acid that can alter some property or aspect of the peptide. In some instances, non-conservative amino acid substitutions can be made, e.g., to change the structure of a peptide, to change the binding properties of a peptide (e.g., to increase or decrease the affinity of binding of the peptide to an analyte and/or to alter increase or decrease the binding specificity of the peptide).

Modifications, including the specific amino acid substitutions, are made by known methods. By way of example, modifications are made by site-specific mutagenesis of nucleotides in the DNA encoding the protein, thereby producing DNA encoding the modification, and thereafter expressing the DNA in recombinant cell culture. Techniques for making substitution mutations at predetermined sites in DNA having a known sequence are well known, for example M13 primer mutagenesis and PCR mutagenesis.

Nucleic Acids

The disclosure also features nucleic acids encoding the biosensors (e.g., SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) described herein, including variants and/or fragments of the biosensors (e.g., variants and/or fragments of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94). These sequences include all degenerate sequences related to the specific polypeptide sequence, i.e., all nucleic acids having a sequence that encodes one particular polypeptide sequence as well as all nucleic acids, including degenerate nucleic acids, encoding the disclosed variants and derivatives of the polypeptide sequences. Thus, while each particular nucleic acid sequence may not be written out herein, it is understood that each and every sequence is in fact disclosed and described herein through the disclosed polypeptide sequences.

In some instances, nucleic acids can encode biosensors with 95, 96, 97, 98, or 99 identity to SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94.

In some instances, nucleic acids can encode SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94 containing 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 20-30, 30-40, or 40-50 conservative amino acid substitutions.

In some instances, nucleic acids can encode SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94 containing 50 or fewer, 40 or fewer, 30 or fewer, 20 or fewer, 10 or fewer, 9 or fewer, 8 or fewer, 7 or fewer, 6 or fewer, 5 or fewer, 4 or fewer, 3 or fewer, or 2 or fewer conservative amino acid substitutions

Also provided herein are vectors comprising the biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) described herein, including variants and/or fragments of the biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94). For example:

Vectors can include nucleic acids that encode biosensors with 95, 96, 97, 98, or 99 identity to SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94.

Vectors can include nucleic acids that encode SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94 containing 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 20-30, 30-40, or 40-50 conservative amino acid substitutions.

Vectors can include nucleic acids that encode SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94 containing 50 or fewer, 40 or fewer, 30 or fewer, 20 or fewer, 10 or fewer, 9 or fewer, 8 or fewer, 7 or fewer, 6 or fewer, 5 or fewer, 4 or fewer, 3 or fewer, or 2 or fewer conservative amino acid substitutions

Examples of suitable vectors include, but are not limited to, plasmids, artificial chromosomes, such as BACs, YACs, or PACs, and viral vectors. As used herein, vectors are agents that transport the disclosed nucleic acids into a cell without degradation and, optionally, include a promoter yielding expression of the nucleic acid molecule in the cells into which it is delivered.

Viral vectors can include, for example, Adenovirus, Adeno-associated virus, herpes virus, Vaccinia virus, Polio virus, Sindbis, and other RNA viruses, including these viruses with the HIV backbone. Any viral families which share the properties of these viruses which make them suitable for use as vectors are suitable. Retroviral vectors, in general are described by Coffin et al., Retroviruses, Cold Spring Harbor Laboratory Press (1997), which is incorporated by reference herein for the vectors and methods of making them. The construction of replication-defective adenoviruses has been described (Berkner et al., J. Virology 61:1213-20 (1987); Massie et al., Mol. Cell. Biol. 6:2872-83 (1986); Haj-Ahmad et al., J. Virology 57:267-74 (1986); Davidson et al., J. Virology 61:1226-39 (1987); Zhang et al., BioTechniques 15:868-72 (1993)). Recombinant adenoviruses have been shown to achieve high efficiency after direct, in vivo delivery to airway epithelium, hepatocytes, vascular endothelium, CNS parenchyma, and a number of other tissue sites. Other useful systems include, for example, replicating and host-restricted non-replicating Vaccinia virus vectors.

Non-viral based vectors can include expression vectors comprising nucleic acid molecules and nucleic acid sequences encoding polypeptides, wherein the nucleic acids are operably linked to an expression control sequence. Suitable vector backbones include, for example, those routinely used in the art such as plasmids, artificial chromosomes, BACs, YACs, or PACs. Numerous vectors and expression systems are commercially available from such corporations as Novagen (Madison, Wis.), Clontech (Pal Alto, Calif.), Stratagene (La Jolla, Calif.), and Invitrogen/Life Technologies (Carlsbad, Calif.). Vectors typically contain one or more regulatory regions. Regulatory regions include, without limitation, promoter sequences, enhancer sequences, response elements, protein recognition sites, inducible elements, protein binding sequences, 5′ and 3′ untranslated regions (UTRs), transcriptional start sites, termination sequences, polyadenylation sequences, and introns.

Promoters controlling transcription from vectors in mammalian host cells may be obtained from various sources, for example, the genomes of viruses such as polyoma, Simian Virus 40 (SV40), adenovirus, retroviruses, hepatitis B virus, and most preferably cytomegalovirus (CMV), or from heterologous mammalian promoters, e.g. β-actin promoter or EF1α promoter, or from hybrid or chimeric promoters (e.g., CMV promoter fused to the β-actin promoter). Of course, promoters from the host cell or related species are also useful herein.

Enhancer generally refers to a sequence of DNA that functions at no fixed distance from the transcription start site and can be either 5′ or 3′ to the transcription unit. Furthermore, enhancers can be within an intron as well as within the coding sequence itself. They are usually between 10 and 300 base pairs in length, and they function in cis. Enhancers usually function to increase transcription from nearby promoters. Enhancers can also contain response elements that mediate the regulation of transcription. While many enhancer sequences are known from mammalian genes (globin, elastase, albumin, fetoprotein, and insulin), enhancers derived from a eukaryotic cell viruses can be used. Examples of such can include the SV40 enhancer on the late side of the replication origin, the cytomegalovirus early promoter enhancer, the polyoma enhancer on the late side of the replication origin, and adenovirus enhancers.

The promoter and/or the enhancer can be inducible (e.g. chemically or physically regulated). A chemically regulated promoter and/or enhancer can, for example, be regulated by the presence of alcohol, tetracycline, a steroid, or a metal. A physically regulated promoter and/or enhancer can, for example, be regulated by environmental factors, such as temperature and light. Optionally, the promoter and/or enhancer region can act as a constitutive promoter and/or enhancer to maximize the expression of the region of the transcription unit to be transcribed. In certain vectors, the promoter and/or enhancer region can be active in a cell type specific manner. Optionally, in certain vectors, the promoter and/or enhancer region can be active in all eukaryotic cells, independent of cell type. Promoters of this type can include the CMV promoter, the SV40 promoter, the β-actin promoter, the EF1α promoter, and the retroviral long terminal repeat (LTR).

The provided vectors also can include, for example, origins of replication and/or markers. A marker gene can confer a selectable phenotype, e.g., antibiotic resistance, on a cell. The marker product is used to determine if the vector has been delivered to the cell and once delivered is being expressed. Examples of selectable markers for mammalian cells are dihydrofolate reductase (DHFR), thymidine kinase, neomycin, neomycin analog G418, hygromycin, puromycin, and blasticidin. When such selectable markers are successfully transferred into a mammalian host cell, the transformed mammalian host cell can survive if placed under selective pressure. Examples of other markers include, for example, the E. coli lacZ gene, green fluorescent protein (GFP), and luciferase. In addition, an expression vector can include a tag sequence designed to facilitate manipulation or detection (e.g., purification or localization) of the expressed polypeptide. Tag sequences, such as GFP, glutathione S-transferase (GST), polyhistidine, c-myc, hemagglutinin, or FLAG™ tag (Kodak; New Haven, Conn.) sequences typically are expressed as a fusion with the encoded polypeptide. Such tags can be inserted anywhere within the polypeptide including at either the carboxyl or amino terminus.

The disclosure further provides cells comprising the biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) described herein, including variants and/or fragments of the biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94). Cells can include, for example, eukaryotic and/or prokaryotic cells. For example, cells can include, but are not limited to cells of E. coli, Pseudomonas, Bacillus, Streptomyces; fungi cells such as yeasts (Saccharomyces, and methylotrophic yeast such as Pichia, Candida, Hansenula, and Torulopsis); and animal cells, such as CHO, Rl.1, B-W and LM cells, African Green Monkey kidney cells (for example, COS 1, COS 7, BSC1, BSC40, and BMT10), insect cells (for example, Sf9), human cells and plant cells. Suitable human cells can include, for example, HeLa cells or human embryonic kidney (HEK) cells. In general, cells that can be used herein are commercially available from, for example, the American Type Culture Collection (ATCC), P.O. Box 1549, Manassas, Va. 20108. See also F. Ausubel et al., Current Protocols in Molecular Biology, John Wiley & Sons, New York, N.Y., (1998).

Optionally, the biosensors (e.g., SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) described herein, including variants and/or fragments of the biosensors (e.g., SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) can be located in the genome of the cell (e.g., can be stably expressed in the cell) or can be transiently expressed in the cell.

Methods of making the provided cells are known and the method of transformation and choice of expression vector will depend on the host system selected. Transformation and transfection methods are described, e.g., in F. Ausubel et al., Current Protocols in Molecular Biology, John Wiley & Sons, New York, N.Y., (1998), and, as described above, expression vectors may be chosen from examples known in the art.

There are a number of compositions and methods which can be used to deliver the nucleic acid molecules and/or polypeptides to cells, either in vitro or in vivo via, for example, expression vectors. These methods and compositions can largely be broken down into two classes: viral based delivery systems and non-viral based deliver systems. Such methods are well known in the art and readily adaptable for use with the compositions and methods described herein.

By way of example, the provided polypeptides and/or nucleic acid molecules can be delivered via virus like particles. Virus like particles (VLPs) consist of viral protein(s) derived from the structural proteins of a virus. Methods for making and using virus like particles are described in, for example, Garcea and Gissmann, Current Opinion in Biotechnology 15:513-7 (2004). The provided polypeptides can be delivered by subviral dense bodies (DBs). DBs transport proteins into target cells by membrane fusion. Methods for making and using DBs are described in, for example, Pepperl-Klindworth et al., Gene Therapy 10:278-84 (2003). The provided polypeptides can be delivered by tegument aggregates. Methods for making and using tegument aggregates are described in International Publication No. WO 2006/110728.

Also provided are transgenic animals comprising one or more cells the biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94) described herein, including variants and/or fragments of the biosensors (e.g, SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94). As used herein, the term animal refers to non-human animals, including, mammals, amphibians and birds. Specifically, examples include sheep, feline, bovines, ovines, pigs, horses, rabbits, guinea pigs, mice, hamsters, rats, non-human primates, and the like. As used herein, transgenic animal refers to any animal, in which one or more of the cells of the animal contain a heterologous nucleic acid. The heterologous nucleic acid can be introduced using known transgenic techniques. The nucleic acid is introduced into the cell, directly or indirectly. For example, the nucleic acid can be introduced into a precursor of the cell or by way of deliberate genetic manipulation, such as by microinjection or by infection with a recombinant virus. The nucleic acid may be integrated within a chromosome, or it may be an extrachromosomally replicating DNA.

Methods for making transgenic animals using a variety of transgenes have been described in Wagner et al. (1981) Proc. Nat. Acad. Sci. USA, 78:5016-5020; Stewart et al. (1982) Science, 217:1046-1048; Constantini et al. (1981) Nature, 294:92-94; Lacy et al. (1983) Cell, 34:343-358; McKnight et al. (1983) Cell, 34:335-341; Brinstar et al. (1983) Nature, 306:332-336; Palmiter et al. (1982) Nature, 300:611-615; Palmiter et al. (1982) Cell, 29:701-710; and Palmiter et al. (1983) Science, 222:809-814. Such methods are also described in U.S. Pat. Nos. 6,175,057; 6,180,849; and 6,133,502.

By way of example, the transgenic animal can be created by introducing a nucleic acid into, for example, an embryonic stem cell, an unfertilized egg, a fertilized egg, a spermatozoon or a germinal cell containing a primordial germinal cell thereof, preferably in the embryogenic stage in the development of a non-human mammal (more preferably in the single-cell or fertilized cell stage and generally before the 8-cell phase). The nucleic acid can be introduced by known means, including, for example, the calcium phosphate method, the electric pulse method, the lipofection method, the agglutination method, the microinjection method, the particle gun method, the DEAE-dextran method and other such method. Optionally, the nucleic acid is introduced into a somatic cell, a living organ, a tissue cell or other cell by gene transformation methods. Cells including the nucleic acid may be fused with the above-described germinal cell by a commonly known cell fusion method to create a transgenic animal.

For embryonic stem (ES) cells, an ES cell line may be employed, or embryonic cells may be obtained freshly from a host, e.g., mouse, rat, guinea pig, and the like. Such cells are grown on an appropriate fibroblast-feeder layer or grown in the presence of appropriate growth factors, such as leukemia inhibiting factor (LIF). When ES cells have been transformed, they may be used to produce transgenic animals. After transformation, the cells are plated onto a feeder layer in an appropriate medium. Cells containing the construct may be detected by employing a selective medium. After sufficient time for colonies to grow, they are picked and analyzed for the occurrence of homologous recombination or integration of the nucleic acid. Those colonies that are positive may then be used for embryo manipulation and blastocyst injection. Blastocysts are obtained from 4 to 6 week old superovulated females. The ES cells are trypsinized, and the modified cells are injected into the blastocoel of the blastocyst. After injection, the blastocysts are returned to each uterine horn of pseudopregnant females. Females are then allowed to go to term and the resulting litters screened for mutant cells having the construct. By providing for a different phenotype of the blastocyst and the ES cells, chimeric progeny can be readily detected. The chimeric animals are screened for the presence of the nucleic acid, and males and females having the modification are mated to produce homozygous progeny transgenic animals.

Kits comprising one or more containers and the nucleic acid sequences, polypeptides, vectors, cells, provided herein, or combinations thereof, are also provided. For example, provided is a kit comprising (i) a nucleic acid sequence encoding a biosensor described herein (e.g, one or more of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94), including variants and/or fragments of the biosensor (e.g, variants or fragments of one or more of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94), (ii) a polypeptide comprising a biosensor described herein (e.g, one or more of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94), including variants and/or fragments of the biosensor (e.g, variants or fragments of one or more of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94), (iii) a vector comprising the nucleic acid of (i), (iv) a cell comprising the nucleic acid or (i) and/or the polypeptide of (ii), (v) a cell comprising the vector of (iii). The kit can comprise any combination of (i)-(v). Optionally, the kit further comprises reagents for using the nucleic acid or peptide biosensors, vectors, and/or cells. For example, if the kit comprises cells, the kit may also comprise cell culture medium. Optionally, the kit further comprises instructions for use. Optionally, the kit further comprises a GPCR, a GPCR-encoding nucleic acid sequence.

Design and Production/Manufacture Methods

Using the methods described herein, it is possible to design, produce, and/or adapt genetically encoded biosensors to assays for a variety of classes of analytes. The provided materials and methods facilitate the discovery of new compounds targeting a wide array of protein targets, including but not limited to: endogenous targets responsible for disease state progression, targets on pathogens for treating infectious diseases, and endogenous targets to be avoided (thus screening early for potential drug side effects and toxicity).

Methods herein provide systematic and generic approaches for the design and production of genetically encoded recombinant peptides containing an analyte-binding framework portion linked (e.g., operably linked) to a signaling portion, wherein the signaling portion is allosterically modulated or regulated by the framework portion upon interaction of the framework portion with an analyte. Generally, methods include: (i) selecting one or more target analytes; (ii) selecting a framework portion (e.g., a PBP) that interacts with (e.g., interacts specifically with) or binds to (e.g., binds specifically to) the target analyte and that undergoes a conformational change upon interacting with or binding to the analyte; (iii) identifying sites or amino acid positions within the framework portion (e.g., the PBP) where the conformational change occurs; and (iv) inserting or cloning a signaling portion into the site or amino acid position identified in (iii). Methods can, optionally, further include: (v) modifying or optimizing linker sequences between the framework portion and the signaling portion, for example, by genetic manipulation (e.g., by point mutation); (vi) modifying or optimizing analyte binding; (vii) modifying the signal generated by the biosensor; and/or (viii) cloning the biosensor into a suitable vector.

In some instances: (iii) includes identification of insertion sites by analysis of the structure (e.g., crystal structure) of the selected framework portion (e.g., the selected PBP) in one or both of its open and closed states to determine amino acid positions at which analyte-binding dependent structural changes occur. In instances where structures for both open and closed states are not available, analysis can be conducted by analogy to a structurally similar framework portion (e.g., PBP); (iv) includes cloning a signaling portion (e.g., a cpFP) at the site identified in (iii) such that the analyte-binding dependent structural change observed in (iii) will result in a conformational change in the signaling portion (e.g., the cpFP) and allosteric modulation of the signaling portion; (v) includes generating a library of mutants of biosensors with distinct linker sequences (e.g., by point mutation), screening the library of mutants to identify mutants with enhanced properties (e.g., improved signal-to-noise ratio), and selecting mutants with enhanced properties (e.g., improved signal-to-noise ratio); (vi) includes increasing or decreasing binding or affinity of the framework portion to the analyte, e.g., by modifying amino acids in the interacting face of the framework portion or regions within the framework portion that are critical for analyte binding; (vii) includes increasing or decreasing signal emission by the signaling portion and/or changing the color of the signal where the signaling portion is a FP (e.g., a cpFP). Methods including (i)-(viii) are exemplified in the Examples section herein.

Methods of Use

The disclosure further provides methods for using the biosensors disclosed herein (e.g., one or more of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94), including variants and/or fragments of the biosensor (e.g., variants or fragments of one or more of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, 53, 62, 63, 77, 78, 91, 92, 93, and/or 94)) to detect analytes, e.g., in biological systems. Such methods can include, for example:

Use of a maltose biosensor disclosed herein (e.g., one or more of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, and/or 53 including variants and/or fragments of SEQ ID NOs: 1, 2, 3, 4, 5, 6, 7, 8, 50, 51, 52, and/or 53) to detect maltose, e.g., in a biological system;

Use of a glutamate biosensor disclosed herein (e.g., one or more of SEQ ID NOs: 62 and/or 63 including variants and/or fragments of SEQ ID NOs: 62 and/or 63) to detect glutamate, e.g., in a biological system;

Use of a phosphonate biosensor disclosed herein (e.g., one or more of SEQ ID NOs: 77 and/or 78 including variants and/or fragments of SEQ ID NOs: 77 and/or 78) to detect phosphonate, e.g., in a biological system; and/or

Use of a glucose biosensor disclosed herein (e.g., one or more of SEQ ID NOs: 91, 92, 93 and/or 94 including variants and/or fragments of SEQ ID NOs: 91, 92, 93 and/or 94) to detect glucose, e.g., in a biological system.

Techniques for performing such methods are known in the art and/or are exemplified herein. For example, methods can include introducing one or more biosensors into a biological system (e.g., a cell); expressing the one or more biosensors in the biological system (e.g., the cell); monitoring the signal emitted by the expressed biosensor in the biological system; and correlating the signal emitted by the expressed biosensor in the biological system with a level of the analyte in the biological system.

EXAMPLES

The invention is further described in the following examples, which do not limit the scope of the invention described in the claims.

Example 1: Maltose Indicators

Genetically encoded maltose indicators were generated using Escherichia coli maltodextrin-binding protein (EcMBP) as a framework and either circularly permuted β-lactamase (cpBla) or circularly permuted fluorescent protein (cpFP) as a signal. Data describe below suggest that cpBla and cpFP are not interchangeable.

Allosteric coupling of ligand binding to fluorescence was hypothesized to require:

i) that the site in into which cpGFP is inserted have the capacity to transduce the global conformational change the scaffold protein (EcMBP in this example) to the local environment of the chromophore in cpGFP; and

ii) that the local environment of the chromophore (e.g., linkers) be optimized to maximize the difference in emission between unbound (apo) and the bound (in this example maltose-bound) states.

Example 1A: Identification of cpGFP Insertion Sites in EcMBP

Potential insertion sites were identified using the crystal structures of the maltose-bound, closed form of EcMBP (Ouiocho et al., Structure, 5:997-1015, 1997) and the ligand-free, open form of EcMBP shown in FIG. 1 (Sharff et al., Biochemistry, 31:10657-10663, 1992) to guide rational design of EcMBP-cpGFP fusions that would result in maltose-dependent GFP fluorescence.

For (i), the change in dihedral angle (defined by the Ca atoms spanning four residues) was analyzed to identify maltose-dependent structural changes in sequentially adjacent residues (FIG. 6); this analysis showed that the Cα chain is “torqued” around residues 175 (ΔDihedral=+41°) and 311 (ΔDihedral=−22°) upon ligand binding. This sequential conformational change was predicted to be coupled to structural changes of an inserted cpGFP, resulting in maltose-dependent fluorescence for the fusion protein.

Previous studies using randomly digested and reassembled circularly permuted β-lactamase (cpBla) and EcMBP showed maltose-dependent β-lactamase activity in proteins with insertions of cpBla at EcMBP residues 165 and 317 (Guntas et al., Chem. Biol., 11:1483-1487, 2004; Guntas and Ostermeier, J. Mol. Biol., 336:263-273, 2004).

Since the ΔDihedral of EcMBP165 is +11° (moderate change) and EcMBP317 is +2° (no real change), four EcMBP-cpGFP templates were constructed by inserting cpGFP into EcMBP at sites 165, 175 (identified herein), 311 (identified herein), and 317 to test our predictive method and the interchangeability of cpBla and cpGFP at sites identified from the EcMBP-cpBla screen. These constructs were named MBP165-cpGFP, MBP175-cpGFP, MBP311-cpGFP, and MBP317-cpGFP (names were modified to encompass variants (e.g., with modified linker sequences). The cpGFP used is cpGFP146 described in Baird et al. (Proc. Natl. Acad. Sci., USA, 96:11241-11246, 1999). PCR assembly was used to construct fusion proteins with GlyGly-linkers between EcMBP and each terminus of cpGFP. The amino acid sequence of each construct is shown in FIGS. 6-9. The sequences of SEQ ID NOs:1-3 shown in FIGS. 7A-7C (i.e., MBP165-cpGFP) differ in the linker sequence between MBP 1-165 and cpGFP 147-238 (linker 1: see the line ending in amino acid 240)). The sequences of SEQ ID NOs: 4-5 shown in FIGS. 8A-8B (i.e., MBP175-cpGFP) differ in the sequence between MBP 1-175 and cpGFP 147-238 (linker 1: see the line ending in amino acid 240)). The sequences of SEQ ID NOs: 6-7 shown in FIGS. 9A-9B (i.e., MBP311-cpGFP) differ in the sequence between cpGFP 1-146 and MBP 312-370 (linker 2: see the line ending in amino acid 640)). Each construct includes 3 linkers: A linker between the C-terminus of the C-terminal portion of MBP and the N-terminus of cpGFP (i.e., linker 2), a linker between the N-terminus of cpGFP and C-terminus of the N-terminal portion of MBP, and a linker in cpGFP (i.e., linker 3).

Example 1B: Linker Optimization

Libraries of variants of SEQ ID NOs: 1-8 were generated with randomized linkers by single-stranded uracil template mutagenesis (see Kunkel et al., Methods Enzymol., 204:125-139, 1991) using the primers listed below:

165 Linker 1 Primers:

PLIAADGxxNVYIM (SEQ ID NO:9)

PLIAADxxNVYIM (SEQ ID NO:10)

PLIAADGGxxNVYIM (SEQ ID NO11)

PLIAADGxPNVYIMG (SEQ ID NO:12)

PLIAADGIxNVYIMG (SEQ ID NO:13)

PLIAADPxSHNVYIM (SEQ ID NO:14)

PLIAADxPSHNVYIM (SEQ ID NO:15)

PLIAADxxSHNVYIM (SEQ ID NO:16)

PLIAADxxSHNVFIM (SEQ ID NO:17)

PLIAADPxSHNVFIM (SEQ ID NO:18)

PLIAADPxSYNVFIM (SEQ ID NO:19)

PLIAADxxSYNVFIM (SEQ ID NO:20)

PLIAADPxSYNVFIM (SEQ ID NO:21)

PLIAADxxSYNVFIM (SEQ ID NO:22)

PLIAADPxSxNVYIM (SEQ ID NO:23)

PLIAADPxSHxVYIM (SEQ ID NO:24)

PLIAADPxSHNxYIM (SEQ ID NO:25)

PLIAADPxSHNVxIM(SEQ ID NO:26)

165 Linker 2 Primers:

KLEYNFNxxYAFKYEN (SEQ ID NO:27)

KLEYNFNxYAFKYEN (SEQ ID NO:28)

KLEYNFNYAFKYEN(SEQ ID NO:29)

KLEYNFxYAFKYEN (SEQ ID NO:30)

KLEYNxxYAFKYEN (SEQ ID NO:31)

KLEYNWxYAFKYEN (SEQ ID NO:32)

KLEYNxKYAFKYEN (SEQ ID NO:33)

KLEYNFNPxYAFKYEN (SEQ ID NO:34)

KLEYNFNxPYAFKYEN (SEQ ID NO:35)

175 Linker 1 Primers:

AFKYENxxSHNVYIM (SEQ ID NO:36)

175 Linker 2 Primers:

KLEYNFNxxKYDIKDV (SEQ ID NO:37)

311 Linker 1 Primers:

KSYEELxxSHNVYIM (SEQ ID NO:38)

KSYEELPxSHNVYIM (SEQ ID NO:39)

KSYEELxPSHNVYIM (SEQ ID NO:40)

311 Linker 2 Primers:

KLEYNFNxxAKDPRIA (SEQ ID NO:41)

KLEYNFNPxAKDPRIA (SEQ ID NO:42)

KLEYNFNxPAKDPRIA (SEQ ID NO:43)

317 Linker 1 Primers:

ELAKDPRxSHNVYIM (SEQ ID NO:44)

ELAKDPRxxSHNVYIM (SEQ ID NO:45)

ELAKDPRxxxSHNVYIM (SEQ ID NO:46)

317 Linker 2 Primers:

KLEYNFNxAATMENA (SEQ ID NO:47)

KLEYNFNxxAATMENA (SEQ ID NO:48)

KLEYNFNxxxAATMENA (SEQ ID NO:49)

Where “x” indicates that a degenerate primer (with DNA sequence “NNS”) was used to encode all 20 possible amino acids.

About 400 variants were screened in semi-high-throughput fashion, measuring fluorescence intensity of clarified cell lysate in the absence and presence of 10 mM maltose.

Insertion of cpGFP as MBP317, a site previously reported for cpBla, did not show maltose-dependent fluorescence (FIG. 11) even though the framework protein still bound maltose, as determined by isothermal titration calorimetry (FIG. 12). These data demonstrate that identification of insertion sites by a method other than insertion of cpGFP (such as insertion of cpBla) is not sufficient to identify sites that transduce ligand binding to changes in fluorescence intensity

Insertion of cpGFP at residue 165 of EcMBP (EcMBP165-cpGFP), another position reported in cpBla studies (Guntas and Ostermeier, supra) with -GlyGly-linkers flanking the cpGFP resulted in a protein in which fluorescence increased 20% (ΔF/F=0.2) upon addition of saturating maltose.

Screening a fully-degenerate, length-two library (“XX”) at either the EcMBP-cpGFP linker (linker 1) or the cpGFP-EcMBP linker (linker 2) yielded proteins with maltose-dependent fluorescent increases >300% or decreases >50% (FIG. 11). Many of the variants with increased ΔF/F values had linkers containing proline(s). Subsequent libraries constructed from oligonucleotides encoding XP or PX and randomization of the residues in GFP from residue 146 to 150 were screened, yielding a final variant with: a two-proline EcMBP-cpGFP linker, a two-glycine cpGFP-EcMBP linker, GFP-H148Y, and GFP-Y151F. This variant, called “EcMBP165-cpGFP.PPYF” (abbreviated PPYF (SEQ ID NO:2)) has a ΔF/F=2.5, a Kd for maltose of 3 μM. Screens also identified variant EcMBP311-cpGFP.L2-NP (-AsnPro- at linker 2 (SEQ ID NO:7)), which has a ΔF/F of 1.0 and a Kd for maltose of 2 μM. This variant has an inferior maltose-dependent fluorescence increase than PPYF, but demonstrates generality of the cpFP insertion method.

EcMBP175-cpGFP was also screened with XX linkers, and a few variants with ΔF/F≈1 were identified (FIG. 11). One mutant, with the first linker encoding HL (EcMBP175-cpGFP.L1-HL (SEQ ID NO:5)), has a ΔF/F=0.5 and a Kd for maltose of 1.3 μM.

These data support that choice of insertion site by structural analysis is preferable to random insertion.

Example 1C: Modifying Ligand Binding and/or Fluorescent Properties of Sensors

One objective in the development of generic biosensors is for the framework to permit independent optimization of binding and signaling properties. Analysis of whether biosensors herein permit such optimization was tested using the high-SNR sensor PPYF, by: (i) rationally altering maltose-binding affinity; (ii) changing the ligand-binding specificity from maltose to sucrose, and (iii) creating a family of sensors in multiple colors.

As a first step, the impacts of mutations of three tryptophan side-chains in the maltose-binding pocket (W230, W62, and W340) were tested. These sites have previously been shown to lower the affinity of EcMBP for maltose by one, two, or three orders of magnitude, respectively, when mutated to alanine (Martineau et al., J. Mol. Biol., 214:337-352, 1990). A mutation to the hinge region, I329W, was also made to PPYF, as this has been shown to increase maltose affinity by about 2-fold in both wild-type EcMBP (Marvin and Hellinga, Nat. Struc. Biol., 8:795-798, 2001) and in the EcMBP-cpBla switches (Guntas et al., Chem. Biol., 11:1483-1487, 2004; Kim and Ostermeier, Arch. Biochem. Biophys., 446:44-51, 2006). As shown in FIG. 13, for the PPYF sensor, the three tryptophan-to-alanine binding-pocket mutations behaved as expected, lowering affinity by between one and three orders of magnitude. In contrast, the I329W mutation did not increase affinity as expected, but rather decreased it. ΔF/F also decreased. This data suggests that the mechanism of fluorescence change in this sensor is dependent on subtle interactions between EcMBP and cpGFP that are linked to the I329W mutation.

As an alternative test for changing the ligand-binding specificity of the sensor while preserving fluorescence signaling, “5-7” mutations (D14L, K15F, W62Y, E111Y), previously shown to confer EcMBP with an affinity for sucrose (Guntas and Mansell, Proc. Natl. Acad. Sci., 102:11224-11229, 2005), were made to PPYF. As shown in FIG. 14A, the mutations conferred to the sensor about 2 mM affinity for sucrose and ˜3 mM affinity for maltose. To address a discrepancy between expected (micromolar) and observed (millimolar) affinity for disaccharides, the 5-7 mutations were made to sensors with cpGFP inserted at different positions in EcMBP, and with different linker compositions. In the context of EcMBP165-cpGFP.PCF, the 5-7 mutations conferred very low (but observable) binding preference for sucrose over maltose (FIG. 14B). The trend of higher (but still weak) affinity for sucrose (˜0.6 mM) over maltose (˜6 mM) continued when the 5-7 mutations are made in the context of EcMBP175-cpGFP.L1-HL (FIG. 14C). In the context of EcMBP311-cpGFP.L2-NP, the 5-7 mutations appeared to eliminate all binding (FIG. 14D). The preference for sucrose over maltose of the 5-7 variants of the sensors is consistent with the binding properties of the 5-7 variants of EcMBP alone and EcMBP-cpBla (Guntas and Mansell, Proc. Natl. Acad. Sci., 102:11224-11229, 2005). The lower affinity for both ligands of the 5-7 variants of the sensors may be the consequence of the inserted cpGFP shifting the open and closed equilibrium.

These data suggest that ligand binding and fluorescent properties of biosensors can be independently modified.

Example 1D: Modifying Sensor Color

The color of GFP can be altered by changing the amino acids that either comprise or interact with the chromophore (see Shaner et al., J. Cell. Sci. 120:4247-4260, 2007, for a review).

Using PPYF as a template, mutations Y66W (to yield a cyan variant, “cpCFP”), L64F+T65G+V68L+T203Y (yellow, “cpYFP”), and Y66H (blue, “cpBFP”) mutations were made (see Cubitt et al., Trends Biochem., 20:448-455, 1995, for exemplary methods). As shown in FIG. 15, the variants exhibit fluorescence emission spectra consistent with their respective intended designs.

The ΔF/F of the color variants in response to maltose is different (in each case inferior) from the ΔF/F of 2.5 observed in PPYF-green. The EcMBP165-cpYFP.PPYF sensor, which has the same covalent chromophore structure as PPYF, has the greatest ΔF/F of the three spectral variants (FIG. 15A). EcMBP165-cpCFP.PPYF has a lower ΔF/F than the green and yellow variants, but by incorporating previously identified mutations, (L1-PC+GFP-Y151F; the resulting protein is called EcMBP165.cpCFP.PCF), a variant with ΔF/F=0.8 was obtained (FIG. 15A).

The EcMBP165-cpBFP.PPYF variant, while dimly fluorescent, is not a sensor, and a screen of 800 linker variants failed to produce any variant with ΔF/F >0.2 (FIG. 16).

Since EcMBP165-cpBFP.PPYF was very dim, Azurite mutations T65S+V150I+V224R were included to increase brightness and stability, and make EcMBP165-cpAzurite a good template for linker screening. Using oligonucleotides encoding XX amino acid linkers, a variant was obtained, EcMBP165-cpAzurite.L2-FE, that had ΔF/F=0.8 (FIG. 15).

Example 1E: Modifying Sensor Color and Ligand Specificity/Affinity

The four sucrose-binding “5-7” mutations described above that conferred weak sucrose affinity in the green sensor (EcMBP165-cpGFP.PPYF) were converted to blue, cyan, and yellow maltose sensors (EcMBP165-cpAzurite.L2-FE, EcMBP165-cpCFP.PCF, and EcMBP165-cpYFP.PPYF). The green and yellow sensors showed increased fluorescence upon addition of 10 mM sucrose, but the cyan and blue proteins did not (FIG. 15A). Like the green variant, the yellow variant had no detectable sucrose affinity with the wild type binding pocket (FIG. 15C) and millimolar affinity for both sugars, with preference for sucrose over maltose (FIG. 15D).

As seen in FIG. 17, as maltose concentration increased, the blue sensor increased in fluorescence first (Kd ˜2.7 then the green (Kd ˜40 then the yellow (Kd ˜350 and at high maltose concentrations, the cyan variant began to increase its fluorescence (Kd ˜1.7 mM).

Example 1F: Imaging Bacteria

The ultimate value of genetically encoded fluorescent sensors is in their utility for observing analyte flux in living cells and organisms. In a simple proof-of-principle experiment, Escherichia coli expressing PPYF or PPYF.T203V (see “Second-generation maltose sensors” below) were imaged in the green fluorescence channel in the absence of maltose, and then re-imaged after addition of saturating maltose to the media.

As shown in FIG. 18, bacteria expressing the sensors clearly became brighter, while control bacteria expressing EGFP appeared unchanged. Increased fluorescence was quantified by measuring the peak (gray-value) pixel intensity of each bacterium. Those expressing PPYF undergo an approximate doubling of fluorescence (bacterium-averaged ΔF/F=1.1±0.4), those expressing PPYF.T203V have slightly increased ΔF/F (ΔF/F=1.29±0.2), while those expressing EGFP have no change in fluorescence (ΔF/F=−0.01±0.05).

Example 1F: 2-Photon Imaging of Mammalian Cells

Multi-photon microscopy opened new frontiers for in vivo fluorescence imaging, in particular for neuronal activity visualization through the use of genetically encoded calcium indicators (Tian et al., Nat. Methods, 3:281-286, 2009; Denk et al., Science, 248:73-76, 1990; Denk and Svoboda, Neuron, 18:351-357, 1997).

To demonstrate that the maltose sensors described herein have the potential to be used for 2-photon imaging, fluorescence excitation spectra were collected. As shown in FIG. 19, with a 535 nm bandpass emission filter (50 nm bp), EcMBP165-cpGFP.PPYF showed a 10-fold maltose-dependent increase in fluorescence when excited at 940 nm. All four spectral variants showed a significant maltose-dependent increase in 2-photon fluorescence.

Example 1G: Sub-Cloning Maltose Sensors

EcMBP165-cpGFP.PPYF.T203V (see “Second-generation maltose sensors” below) were cloned into a modified version of the pDisplay vector (Invitrogen) for extracellular display on the surface of transiently transfected human embryonic kidney (HEK293) cells.

As shown in FIG. 20, the sensor localized to the plasma membrane and increased in brightness in a concentration-dependent manner when perfused with buffers of varying maltose concentration. The ΔF/F is 5.8-fold, very close to that of the soluble protein produced in E. coli, with the mid-point of the maltose-dependent fluorescence increase being 6.5 μM (FIG. 21A), very similar to the affinity determined on purified protein (5 μM). Furthermore, the surface displayed sensor responded rapidly to a pulse of 1 mM maltose (FIG. 21A), indicating that the time course for its action is useful for transient events.

Example 1H: Crystal Structure Analysis of Maltose Sensors

High-resolution structures of several of the maltose sensors described above were generated. Crystallization trials were performed with EcMBP165-cpGFP.PPYF, EcMBP175-cpGFP.L1-HL, and EcMBP311-cpGFP.L2-NP in the presence and absence of excess maltose, from which both EcMBP175-cpGFP.L1-HL and EcMBP311-cpGFP.L2-NP crystallized in the presence of maltose. X-ray structures were solved to 1.9 and 2.0 Å resolution, respectively, by molecular replacement (FIGS. 22A-22C).

The structures of the cpGFP and EcMBP domains of the sensors are superimposable with published crystal structures of cpGFP (from GCaMP2; RMSD=0.36 and 0.38 Å, respectively, for comparing 221 common Cα atoms) and EcMBP-maltose (RMSD=0.43 and 0.37 Å, 370 Cα). The structure of EcMBP is largely unperturbed by insertion of the cpGFP domain; only residues around the 175 and 311 insertion sites showed any significant displacement.

GFP-H148, which H-bonds the GFP chromophore in the structure of native GFP, also directly H-bonded to the chromophore in the EcMBP175-cpGFP.L1-HL- maltose structure (FIG. 22B), although a different rotamer was observed. In the EcMBP311-cpGFP.L2-NP-maltose structure, GFP-H148 is pulled away from the chromophore and is largely replaced by the Asn from linker 2, which makes H-bond interactions to both strand 8 of the GFP barrel and the chromophore phenolate oxygen (through a water molecule, FIG. 22D). GFP-H148, meanwhile, seemed to stabilize the conformation of linker 2 of EcMBP311-cpGFP.L2-NP by H-bonding the backbone carbonyl of the linker 2 Asn. There is some solvent access to the cpGFP chromophore through the hole in the GFP barrel created by circular permutation, although the inter-domain linkers block much of the opening in both structures. Relatively few contacts are made between the cpGFP and EcMBP domains.

Based on the structures of two maltose-bound sensors, the sensing mechanism likely involves a shift in the relative position of linker 1 and linker 2 induced by the conformational change in the EcMBP domain associated with maltose binding (FIG. 5). The register shift of interactions between the two linkers could alter the proximity of linker 2 and nearby side-chains to the cpGFP chromophore and change the water structure in the cpGFP opening, leading to a shift in the chromophore protonation equilibrium. This might explain why rigid proline is preferred in either linker, since conformational changes upon ligand binding might be better propagated through the rigid linkers to the cpGFP chromophore environment.

Example 1I: Generation of Second-Generation Maltose Sensors

In an attempt to increase brightness and ΔF/F of GCaMP, the local environment of the chromophore was altered by randomizing residues within cpGFP, and screening for improved variants (Tian et al., nat. Methods, 6:875-881, 2009).

As shown in FIG. 23, in the context of EcMBP165-cpGFP.PPYF, the T203V mutation decreases the fluorescence emission of the apo-state by half (FIG. 23A), while saturated fluorescence and affinity are unchanged (FIG. 23B), increasing ΔF/F to 6.5. In the maltose-saturated state, PPYF itself has about a quarter the brightness of EGFP, and half the brightness of cpGFP.

In the context of EcMBP311-cpGFP.L2-NP, the T203 V mutation decreases the brightness of both the apo-state and the saturated-state equally, resulting in no significant change in ΔF/F (FIGS. 23C and D).

These results indicate that the benefits of the T203V mutation are not universally transferable, and that cpGFP-based fluorescent sensors need to be optimized individually.

Example 2: Maltotriose Indicators

Genetically encoded maltotriose indicators were created using Pyrococcus furiosus maltotriose binding protein. As described below, only the structure of the ligand-bound state P. furiosus maltotriose binding protein (PfMBP) is available. As shown in FIGS. 1 and 2, PfMBP is homologous to EcMBP (compare FIGS. 1 and 2). Two sensors were made, PfMBP171 and PfMBP316, the insertion points for which were selected based on homology to EcMBP165 and EcMBP311, respectively. Linkers were optimized. PfMBP sensors have a ΔF/F of −1.2.

Pyrococcus furiosus is a thermophilic organism. Proteins from thermophiles have been shown to be more amenable to mutation than those from mesophiles (Bloom et al., Proc. Natl. Acad. Sci., 103:5869-5874, 2006). As an alternative to developing new sensors by inserting cpGFP into PBPs, it should also be possible to generate new sensors by changing the ligand-binding specificity of an existing PBP-based sensor.

It has previously been shown that the binding sites of PBPs can be reengineered to accommodate novel ligands (Looger et al., Nature, 423:185-190, 2003). However, those re-design efforts used framework proteins from mesophiles and suffered from poor stability. We hypothesized that PfMBP, which is intrinsically more stable than EcMBP, is more tolerant of mutations. To test this hypothesis, we characterized and compared the stability of PfMBP to EcMBP, PfMBP-cpGFP sensors to EcMBP-cpGFP sensors, PfMBP binding site mutants to EcMBP binding site mutants, and PfMBP-cpGFP sensor binding site mutants to EcMBP-cpGFP sensor binding site mutants. Conclusively, the PfMBP variants were more stable than the EcMBP variants. Finally, we demonstrate that the increased thermo-stability of the PfMBP-cpGFP sensors is useful for the measurement of maltotriose at temperatures as high at 60° C., whereas the EcMBP-cpGFP sensors are only useful for the measurement of maltose at temperatures as high as 40° C.

Example 2A: Identification of cpGFP Insertion Sites in PfMBP

The ligand-bound (closed) structure of PfMBP is available (Evdokimov et al., J. Mol. Biol., 305:891-904, 2001), but the unbound structure is not. Accordingly, insertion sites for the PfMBP-cpGFP sensors were identified by homology to EcMBP.

Sites were selected based on the structural similarities between PfMBP and EcMBP. Two sites were selected. One of these sites is EcMBP311, which is homologous to PfMBP316. This site is at juncture between the end of the cluster of helices (Helices 8a, 8b, 8c) and the start of the “equatorial” spanning helix (Helix 9). Another site that was made into a sensor in EcMBP was EcMBP165, which is homologous to PfMBP171. cpGFP was inserted into PfMBP at each of these sites. The sequences of the resulting constructs, PfMBP171-cpGFP and PfMBP316-cpGFP, are shown in FIGS. 24 and 25, respectively.

Example 2B: Linker Optimization

Libraries of variants of SEQ ID NOs: 50-53 were generated with randomized linkers by single-stranded uracil template mutagenesis using the primers listed below:

175 Linker 1 Primers:

AIAQAFxxSHNVYIMA (SEQ ID NO:54)

AIAQAFPxSHNVYIMA (SEQ ID NO:55)

171 Linker 2 Primers:

KLEYNFNxxYYFDDKTE (SEQ ID NO:56)

316 Linker1 Primers

VLDDPExxHNVYIM (SEQ ID NO:57)

VLDDPEIxxSHNVYIM (SEQ ID NO:58)

316 Linker2 Primers

KLEYNFxxNDPVIY (SEQ ID NO:59)

KLEYNFNxPKNDPVIY (SEQ ID NO:60)

KLEYNFNPxKNDPVIY (SEQ ID NO:61)

Where “x” indicates that a degenerate primer (with DNA sequence “NNS”) was used to encode all 20 possible amino acids.

Several thousand variants were screened in semi-high-throughput fashion, measuring fluorescence intensity of clarified cell lysate in the absence and presence of 1 mM maltotriose.

Screening a fully-degenerate, length-two library (“XX”) at either the PfMBP171-cpGFP linker (linker 1) or the cpGFP-PfMBP linker (linker 2) yielded proteins with maltotriose-dependent fluorescent increases >100% or decreases >20% (FIG. 26A). A variant from this group with a GlyGly PfMBP-cpGFP linker and a PheGlu cpGFP-PfMBP linker was selected for further characterization. This variant, called “PfMBP171-cpGFP.L2FE” has a ΔF/F=1.2, a Kd for maltotriose of <1 μM.

Screening a fully-degenerate, length-two library (“XX”) at either the PfMBP316-cpGFP linker (linker 1) or the cpGFP-PfMBP linker (linker 2) also yielded proteins with maltotriose-dependent fluorescent increases >100% or decreases >20% (FIG. 26B). A variant from this group with a GlyGly PfMBP-cpGFP linker and a PheGlu cpGFP-PfMBP linker was selected for further characterization. This variant, called “PfMBP316-cpGFP.L1-NP” has a ΔF/F=1.2, a Kd for maltotriose of 40 μM.

These data support that structurally homologous frameworks can be compared to identify insertion sites for cpGFP.

Example 2C: Characterization of the Thermostability of the PfMBP and PfMBP-cpGFP Compared to EcMBP and EcMBP-cpGFP

Thermal stability of PfMBP171-cpGFP.L2FE was measured using circular-dichroism (CD) and compared to the original EcMBP and PfMBP binding proteins, along with cpGFP. Following the changes by means of CD allowed determination of whether different transitions happened in alpha, beta, or both kinds of structures. Given that cpGFP is a beta barrel, strong transitions in the beta signal alone were associated with changes in this kind of structure. In the same way, transitions in both kinds of signals were associated with the binding protein structure. As shown in FIG. 27A, PfMBP is significantly more thermo-stable than EcMBP. In fact, while EcMBP denatured at about 50° C., PfMBP did not denature at temperatures less than 80° C. Also, the addition of maltose to EcMBP stabilized the protein by about 10° C.

As shown in FIG. 27B, the stability of the EcMBP component of the EcMBP165-cpGFP.PPYF sensor decreased from 50° C. to 45° C. with insertion of cpGFP, while the intrinsic stability of cpGFP in the sensor remained unchanged. There was little change in the stability of the PfMBP component of the PfMBP171-cpGFP.L2FE sensor with insertion of cpGFP (FIG. 27B). Moreover, PfMBP seemed to exert a small stabilizing effect over the inserted cpGFP, as shown by the change in the steepness and melting point of the curve of the soluble form and the PfMBP171-cpGFP.L2FE sensor. All the associations made between transitions and domain unfolding were supported by CD spectra taken at the beginning and the end of each temperature ramp.

Analysis of whether the PfMBP scaffold was more tolerant of mutation than the EcMBP scaffold was also performed. Proof-of-principle mutations were made to the ligand-binding sites of EcMBP and PfMBP, and their respective sensors. In EcMBP, Asn12 was mutated to Trp to result in steric clashes with the surrounding residues, and backbone, of the binding pocket. The homologous mutation in PfMBP is Ala13Trp, which would be expected to have the same effect.

As shown in FIG. 27C, N12W decreased the Tm of EcMBP from 50° C. to 40° C., while the corresponding mutation in PfMBP, A13W, had no noticeable effect. This data confirms that the thermo-philic protein is more tolerant of mutations to the binding site. Furthermore, in the context of the sensors, the N12W mutation to EcMBP165-cpGFP.PPYF completely destabilized the binding protein component of the sensor (FIG. 27D), while the A13W mutation in PfMBP171-cpGFP.L2FE had no effect on stability (FIG. 27D).

Example 2D: Tolerance of PfMBP Sensor to Increased Temperature

Fluorescence of the protein in the apo and ligand-bound states at was measured at different temperatures.

As shown in FIG. 28A, fluorescence of the EcMBP165-cpGFP.PPYF sensor in the bound state was higher than it is in the apo-state at lower temperatures, by about 4-fold. However, at around 55° C. (the unfolding transition of the EcMBP component) the fluorescence of the EcMBP165-cpGFP.PPYF sensor dropped precipitously. As a result, EcMBP165-cpGFP.PPYF is unsuitable for detection of maltose at temperatures greater than 50° C. (FIG. 28B). In contrast, PfMBP171-cpGFP.L2FE retained its maltotriose binding capabilities at high temperatures (FIGS. 28A and 28B), and is limited only by the intrinsic fluorescence of the cpGFP component, which decays at about 80° C. (FIG. 28A).

Example 2E: Measurement of Maltodextrins in Hot Liquids

To demonstrate that the soluble and immobilized sensors function similarly, PfMBP171-cpGFP.L2FE, PfMBP316-cpGFPL1XXX, and EcMBP165-cpGFP.PPYF.T203V were immobilized via their N-terminal poly-histidine tags on to the surface of Ni-NTA coated glass. In a fluorescence plate reader, the immobilized proteins performed similarly to their soluble counterparts (see FIGS. 28C, 28D, and 28F).

Next, a prototype device was constructed, with a light guide providing the excitation light and returning the fluorescent emitted light back to the photodetector, the bio-sensor protein immobilized to Ni-NTA coated coverslips, and the coverslip attached to the end of the light guide. The “wand” of the detector was dipped into different compositions of solutions, each with varying concentrations of maltose or maltotriose. Experiments were performed at different temperatures. PfMBP-cpGFP sensor performed better at higher temperatures (as high as 60° C.) than the EcMBP-cpGFP sensor.

Example 3: Glutamate Indicators

Glutamate indicators were created from Escherichia coli glutamate-binding protein (EcYbeJ). As with PfMBP in Example 2, only the structure of the ligand-bound EcYbeJ is available. EcYbeJ is homologous to EcMBP, but to a lesser degree. The best homology match between a site in EcYbeJ and a site in a binding protein for which an intensity-based sensor has already been created is EcYbeJ253 and EcMBP311 (described herein). As shown in FIG. 3, both sites are at the junction of “Rising Helix 8” and the “Equatorial Helix/Coil.” The amino acid composition of the cpGFP and EcYbeJ junction was made the same as that of the EcMBP311-cpGFP sensor (Linker 2=NP). The amino acid composition of the EcYbeJ junction and cpGFP was optimized to LV (Linker 1=LV). The variant has a ΔF/F of 5.

Example 3A: Identification of cpGFP Insertion Sites

The ligand-bound (closed) structure of Shigella flexneri glutamate binding protein is available (Fan et al., Protein Pept. Lett., 13:513-516, 2006). This protein has only 4 amino acid mutations relative to EcYbeJ, and is thus an appropriate model.

Insertion sites for the EcYbeJ-cpGFP sensors were identified by homology to EcMBP. Based on the topology map (FIG. 3), position 311 in EcMBP was identified as an acceptable insertion site for EcYbeJ. EcMBP311 is equivalent to EcYbeJ253. EcYbeJ253 is at juncture between the end of the cluster of helices (Helices 8a, 8b, 8c) and the start of the “equatorial” spanning helix (Helix 9). In YbeJ, the structure that is homologous to the equatorial helix is the equatorial coil (depicted in red, to match the red coloring of Helix 9).

Intrinsic affinity of wild-type YbeJ for glutamate (˜1 μM) was too high to permit high-throughput screening of linker libraries. Endogenous glutamate (from the growth media) saturates the sensor, making measurement of the unbound state technically challenging. A mutation to YbeJ (A184V), in the “hinge” of the protein were made. Mutation of this residue to Trp or Arg have previously been shown to decrease affinity in FRET-based sensors (see Okumoto et al., Proc. Natl. Acad. Sci., 102:8740-8745, 2005). EcYbeJ253 (A184V)-cpGFP has an affinity for glutamate of about 100 μM. All references to EcYbeJ253-cpGFP, unless otherwise noted, refer to the A184V variant. The sequences of the EcYbeJ constructs are shown in FIG. 29.

Example 3B: Linker Optimization

Libraries of variants of SEQ ID NOs: 62-63 were generated with randomized linkers by single-stranded uracil template mutagenesis using the primers listed below:

253 Linker 1 Primers:

FKNPIPPxSHNVYIMA (SEQ ID NO:64)

FKNPIPPxxSHNVYIMA (SEQ ID NO:65)

FKNPIPPPxSHNVYIMA (SEQ ID NO:66)

FKNPIPPxPSHNVYIMA (SEQ ID NO:67)

KWFKNPIxxSHNVYIMA(SEQ ID NO:68)

FKNPIPPxxNVYIMAD (SEQ ID NO:69)

KWFKNPIxxNVYIMAD (SEQ ID NO:70)

253 Linker 2 Primers:

KLEYNFNxKNLNMNF (SEQ ID NO:71)

KLEYNFNxxKNLNMNF (SEQ ID NO:72)

KLEYNFNxPKNLNMNF (SEQ ID NO:73)

KLEYNFNPxKNLNMNF (SEQ ID NO:74)

GHKLEYNxxLNMNF (SEQ ID NO:75)

KLEYNFNxxLNMNF (SEQ ID NO:76)

Where “x” indicates that a degenerate primer (with DNA sequence “NNS”) was used to encode all 20 possible amino acids.

Several thousand variants were screened in semi-high-throughput fashion, measuring fluorescence intensity of clarified cell lysate in the absence and presence of 10 mM glutamate.

Screening a fully-degenerate, length-two library (“XX”) at the EcYbeJ253-cpGFP linker (linker 1) identified a sensor with glutamate-dependent fluorescent increases of 100%. This variant has a LeuVal EcYbeJ-cpGFP linker (L1-LV) and was used as the framework for optimization of the cpGFP-EcYbeJ253 linker (linker 2). The results of that screen yielded a protein with glutamate-dependent fluorescent increase of −500% and a linker 2 composition of AsnPro. As shown in FIG. 30, this variant, called “EcYbeJ253-cpGFP.L1LVL2NP” has a ΔF/F=5, a Kd for glutamate of 100 μM. Interestingly, the composition of the second linker, AsnPro, is the same as the linker composition of EcMBP311-cpGFP.L2NP.

Example 3C: Detection of Extracellular Glutamate

EcYbeJ253-cpGFP.L1LVL2NP was cloned into the pDisplay™ vector to allow targeting and anchoring of the sensor to the plasma membrane. The resulting construct was transfected into cultured mammalian cells (HEK293) to visualize the addition of glutamate to extracellular media. Constructs were also generated in a bacterial expression vector with the epitope tags individually and in combination.

As shown in FIG. 31, the hemagglutinin tag interferes with the fluorescence change. EcYbeJ253-cpGFP.L1LVL2NP was re-cloned into a derivative of the pDisplay™ vector, lacking the hemagglutinin tag, called pMinDis (for Minimal Display). This new construct, when expressed in HEK293 cells, shows a change in fluorescence intensity under 2-photon excitation that is approximately the same as the soluble protein (see FIG. 32) with higher affinity, of about 1 (see FIG. 32).

To demonstrate that the sensor is functional in neurons, and not just cultured HEK cells, the gene from EcYbeJ253-cpGFP.L1LVL2NP was cloned into an adeno-associated virus vector (AAV) under control of the synapsin promoter. Virus particles were generated and used to infect cultured primary hippocampus neurons from rats 7 days after culturing. 14 days after culturing (and 7 days after infection), the infected neurons were imaged under 2-photon microscopy (FIG. 33).

Example 4: Phosphonate Indicators

An indicator for phosphonate compounds was created from Escherichia coli phosphonate-binding protein (EcPhnD). In this instance, only the structure of the ligand-bound state was available at the time the sensor was conceived. EcPhnD is homologous to EcMBP to a lesser degree and to EcYbeJ to a greater degree. The best homology match between a site in EcPhnD and a site in a binding protein for which an intensity-based sensor has already been created is EcPhnD90 and EcYbeJ253. There is no “Rising Helix 8” in EcPhnD, but there is an “Equatorial Helix/Coil” (FIG. 4). cpGFP was inserted at the Equatorial Helix/Coil and linkers were optimized to yield a sensor with ΔF/F of 1.2. EcPhnD is a dimmer, so, a pair of mutations (L297R+L301R) were made to convert it to a monomer. The monomer variant has a ΔF/F of 1.6.

Example 4A: Identification of cpGFP Insertion Sites in EcPhnD

Insertion sites for the EcPhnD-cpGFP sensors were identified using the ligand-bound (closed) structure of EcPhnD by homology to EcMBP. Based on the topology map (FIG. 4), position 311 in EcMBP was identified as an acceptable insertion site in EcPhnD. EcMBP311 corresponds to EcPhnD90. This site is at the point where the rising strand (Strand D) of EcPhnD has a small bend in it that runs equatorial to the rest of the sheets in the protein. Even though it is topologically different from the “equatorial” spanning helix (Helix 9) of EcMBP its equatorial alignment is similar, and with just the closed structure at the time, in an environment that was expected to undergo significant dihedral change upon binding ligand. Sequences of EcPhnD constructs are shown in FIG. 34.

Example 4B: Linker Optimization

Libraries of variants of SEQ ID NOs: 77-78 were generated with randomized linkers by single-stranded uracil template mutagenesis using the primers listed below:

90 Linker 1 Primers:

QTVAADGSSHNVYIMA (SEQ ID NO:79)

QTVAADxxSHNVYIMA (SEQ ID NO:80)

QTVAADxPSHNVYIMA (SEQ ID NO:81)

QTVAADPxSHNVYIMA (SEQ ID NO:82)

QTVAADxxNVYIMA (SEQ ID NO:83)

QTVAADxxSHNVYIMA (SEQ ID NO:84)

VFQTVAxxSHNVYIMA (SEQ ID NO:85)

90 Linker 2 Primers:

HKLEYNFNPGYWSVLI (SEQ ID NO:86)

HKLEYNFNxxPGYWSVLI (SEQ ID NO:87)

HKLEYNxxPGYWSVLI (SEQ ID NO:88)

HKLEYNFNxxYWSVLI (SEQ ID NO:89)

HKLEYNFNPxYWSVLI (SEQ ID NO:90)

Where “x” indicates that a degenerate primer (with DNA sequence “NNS”) was used to encode all 20 possible amino acids.

Several thousand variants were screened in semi-high-throughput fashion, measuring fluorescence intensity of clarified cell lysate in the absence and presence of 100 uM 2AEP.

Screening a number of fully-degenerate, libraries at the EcPhnD90-cpGFP linker (linker 1) yielded a protein with 2AEP-dependent fluorescent increases of >100%. This variant has a AlaAsp EcPhnD-cpGFP linker (L1-AD) and a ΔF/F of 1.2. The variant came from a linker that also deleted two residues, effectively making the insertion point of cpGFP occur after residue D88, and then skipping to residue P91 at the cpGFP-EcPhnD linker.

It was observed from the crystal structure that EcPhnD forms a dimer. To disrupt the dimer inter-face and potentially simplify the observable binding behavior of the EcPhnD protein, two mutations, L297R and L301R, were introduced into the dimerization helices. These mutations were expected, by charge repulsion, to disrupt the dimer interface. As shown in FIG. 35, incorporation of L279R and L301R mutations into EcPhnD90-cpGFP.L1AD caused ΔF/F to increases to 1.6 in response to 2AEP.

Further attempts to crystallize the open, ligand-unbound form of the protein were successful after making a mutation to the binding site, H157A, that substantially decreased affinity for phosphonate compounds. This mutant was crystallized in the absence of ligand, and the open state of the protein solved. The ΔDihedral analysis (FIG. 36) showed that the region of greatest dihedral change was the group of residues from 88-90, just one amino acid away from the site chosen by homology to the equatorial helix.

These data further indicate that ΔDihedral metric is sufficient for identifying sites in PBPs into which cpGFP can be inserted and result in intensity-based fluorescent sensors.

Example 5: Glucose Indicators

Glucose indicators were created from Thermus thermophilus glucose binding protein (TtGBP). In this instance, only the structure of the ligand-bound state is available. TtGBP is very homologous to EcMBP and PfMBP (compare FIG. 5 with FIGS. 1 and 2). The insertion point (TtGBP326) was chosen by homology to EcMBP311 and PfMBP316. The amino acid composition of the cpGFP and TtGBP junction was made the same as that of the EcMBP311-cpGFP and EcYbeJ253 sensors (Linker 2=NP). Linker 1 was optimized (Linker 1=PA) and the TtGBP326 sensor have a ΔF/F of −2.5. To improve its utility for the measuring glucose concentrations in human blood, the affinity was weakened from its native ˜1 μM to 1.5 mM by mutation of two residues in the binding pocket (H66A+H348A).

Example 5A: Identification of cpGFP Insertion Sites in TtGBP

The ligand-bound (closed) structure of TtGBP is available (Cuneo et al., J. Mol. Biol., 362:259-270, 2006). Accordingly, insertion sites for the TtGBP-cpGFP sensors were identified by homology to EcMBP and PfMBP. Based on the topology map (FIG. 5), it is apparent that TtGBP, PfMBP, and EcMBP are structurally similar in the closed, ligand-bound state. Positions in EcMBP determined by the dihedral analysis (see above) were predicted to be acceptable insertion sites in TtGBP. EcMBP311 is homologous to TtGBP326. This site is at juncture between the end of the cluster of helices (Helices 8a, 8b, 8c) and the start of the “equatorial” spanning helix (Helix 9). The amino acid sequence of the TtGBP construct is shown in FIG. 37.

Example 5B: Linker Optimization

Libraries of variants of SEQ ID NO:91 were generated with randomized linkers by single-stranded uracil template mutagenesis using the primers listed below:

326 Linker 1 Primers:

DSDPSKYxxSHNVYIM (SEQ ID NO:95)

DSDPSKYPxSHNVYIM (SEQ ID NO:96)

DSDPSKYxPSHNVYIM (SEQ ID NO:97)

RLDSDPSxxSHNVYIM (SEQ ID NO:98)

DSDPSKYxxNVYIM (SEQ ID NO:99)

326 Linker 2 Primers:

KLEYNFNxxNAYGQSA (SEQ ID NO:100)

KLEYNFxxPNAYGQSA (SEQ ID NO:101)

GHKLEYNxxNAYGQSA (SEQ ID NO:102)

KLEYNFNxPNAYGQSA (SEQ ID NO:103)

KLEYNFNPxNAYGQSA (SEQ ID NO:104)

Where “x” indicates that a degenerate primer (with DNA sequence “NNS”) was used to encode all 20 possible amino acids.

Several hundred variants were screen in semi-high-throughput fashion, measuring fluorescence intensity of clarified cell lysate in the absence and presence of 10 mM glucose.

Linker 1 was optimized (Linker 1=PA) and the TtGBP326-cpGFP.L1PAL2NP sensor has a ΔF/F of −2.5 (see FIG. 38). Additionally, the TtGBP sensor was tested with and without the N-terminal pRSET tag and no difference was observed. Specifically, both sensors exhibited an affinity for glucose of about 1.5 mM and a ΔF/F of 2.5.

Data showing that it was possible to construct a glucose sensor by replacing the EcMBP or PfMBP with TtGBP, retaining the composition of linker 2, and optimizing the composition of linker 1, indicates that the methods for generating sensors disclosed herein can be used to generate sensors using any suitable framework.

Example 5C: Detecting Changes in Glucose Concentration in Vivo

The TtGBP326-cpGFP.L1PAL2NP sensor was cloned into a variant of the pDisplay™ vector lacking the N-terminal secretion sequence, the N-terminal hemagglutinin tag, the C-terminal cMyc tag, and the C-terminal PDGFR membrane anchoring domain.

The TtGBP sensor was cloned into a mammalian expression vector (based on the pDisplay™ vector described in Example 3 above) with the secretion, epitope, and transmembrane anchoring peptides removed, thus resulting in cytosolic expression of the TtGBP326-cpGFP.L1PAL2NP+H66A+H348A sensor. The construct was transfected into HEK293 cells. As shown in FIG. 39, the TtGBP sensor was expressed in the cytosol.

As shown in FIG. 40, addition of 10 mM glucose to the media increases fluorescence.

The TtGBP326-cpGFP.L1PAL2NP+H66A+H348A sensor was further modified by L276V mutation to produce TtGBP326.L1PA.L2NP.H66A.H348A.L276V (see FIG. 50). As shown in FIG. 51, this construct has an affinity for glucose of 6.5 mM.

Additionally, the TtGBP326.L1P1.L2NP.G66A.H348A.L276V was cloned into the pMinDis derivative of the pDisplay vector and expressed on the extracellular surface of HEK293 cells. After exchanging the HEK293 cell media for PBS, addition of glucose to the PBS led to an increase in fluorescence (see FIG. 52).

These data indicate, in part, that the pRSET tag is not essential to the function of the sensor and that the TtGBP326-cpGFP.L1PAL2NP sensor is capable of detecting changes in the concentration of glucose inside or on the external surface of human cells.

Other Embodiments

It is to be understood that while the invention has been described in conjunction with the detailed description thereof, the foregoing description is intended to illustrate and not limit the scope of the invention, which is defined by the scope of the appended claims. Other aspects, advantages, and modifications are within the scope of the following claims. 

What is claimed is:
 1. A recombinant peptide biosensor comprising an analyte-binding framework portion and a signaling portion, wherein the signaling portion is present within the framework portion at a site or amino acid position that undergoes a conformational change upon interaction of the framework portion with a defined, specific, or selected analyte, wherein the recombinant peptide biosensor comprises an amino acid sequence having at least 85% identity to a sequence selected from the group consisting of SEQ ID NO: 91, 92, 93, and
 94. 2. The recombinant peptide biosensor of claim 1, wherein the signaling portion is allosterically regulated by the framework portion such that signaling from the signaling portion is altered upon interaction of the framework portion with the analyte.
 3. The recombinant peptide biosensor of claim 1, wherein signaling by the signaling portion detectably increases upon interaction of the framework portion with the analyte.
 4. The recombinant peptide biosensor of claim 1, wherein signaling by the signaling portion detectably decreases upon interaction of the framework portion with the analyte.
 5. The recombinant peptide biosensor of claim 1, wherein signaling by the signaling portion is proportional to the level of interaction between the framework portion and the analyte.
 6. The recombinant peptide biosensor of claim 1, wherein the framework portion has a first structure in the absence of an analyte and a second structure, that is detectably distinct from the first structure, in the presence of the analyte.
 7. The recombinant peptide biosensor of claim 6, wherein the conformational change between the first structure and the second structure allosterically regulates the signaling portion.
 8. The recombinant peptide biosensor of claim 1, wherein the framework portion is a periplasmic binding protein (PBP) or a variant of a PBP.
 9. The recombinant peptide biosensor of claim 1, wherein the signaling portion is a circularly permuted fluorescent protein (cpFP).
 10. The recombinant peptide biosensor of claim 1, wherein the analyte-binding framework portion binds specifically to glucose.
 11. A recombinant peptide biosensor comprising an amino acid sequence with at least 95% identity to a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 91, 92, 93, and 94, wherein the recombinant peptide biosensor binds specifically to glucose.
 12. The recombinant peptide biosensor of claim 11, comprising a recombinant peptide biosensor selected from the group consisting of SEQ ID NO: 91, 92, 93, and
 94. 13. A nucleic acid encoding the recombinant peptide biosensor of claim 1 or claim
 11. 14. A vector comprising the nucleic acid of claim
 13. 15. A cell comprising the nucleic acid of claim
 13. 16. A cell comprising the vector of claim
 14. 17. A method for detecting glucose, the method comprising detecting a level of fluorescence emitted by the recombinant peptide biosensor of claim 1, and correlating the level of fluorescence with the presence of glucose.
 18. The method of claim 17, wherein the recombinant peptide biosensor is expressed from a nucleic acid.
 19. The method of claim 17, comprising contacting the recombinant peptide biosensor with a sample comprising glucose.
 20. The method of claim 17, comprising correlating the level of fluorescence with a concentration of glucose.
 21. The method of claim 20, comprising comparing the level of fluorescence with a level of fluorescence emitted by the recombinant peptide biosensor in the presence of a sample comprising a known concentration or range of concentrations of glucose.
 22. A method for detecting glucose, the method comprising detecting a level of fluorescence emitted by a recombinant peptide biosensor expressed from the nucleic acid of claim 13 and correlating the level of fluorescence with the presence of glucose.
 23. The method of claim 22, comprising contacting the recombinant peptide biosensor with a sample comprising the glucose.
 24. The method of claim 23, comprising correlating the level of fluorescence with a concentration of the glucose.
 25. The method of claim 24, comprising comparing the level of fluorescence with a level of fluorescence emitted by the recombinant peptide biosensor in the presence of a sample comprising a known concentration or range of concentrations of the glucose. 